Method and apparatus for bonding polarizing plate

ABSTRACT

Method and apparatus for bonding a polarizing plate high in operating efficiency and yield. The apparatus includes a cutting unit for cutting at least a polarizing plate of a strip-shaped film, composed of the polarizing plate and a release film bonded to the polarizing plate, leaving the release film uncut, when a forward end side pre-severed end face of the strip-shaped film perpendicular to the longitudinal direction of the strip-shaped film has traveled up to a length corresponding to a length of a substrate, to form a film piece, a release film separating unit for separating the release film from the film piece thus severed, and a bonding unit for bonding the tacky surface of the film piece freed of the release film to a mating position of the substrate so that the forward end side end face of the transported substrate is parallel to the pre-severed end face of the film piece.

FIELD OF THE INVENTION

This invention relates to a method and an apparatus for bonding apolarizing plate to a substrate. This invention also relatesspecifically to a method and an apparatus for bonding a polarizing plateto each of both surfaces of the substrate and, more specifically, to amethod and an apparatus for continuously bonding the polarizing plates.

BACKGROUND

As a liquid crystal display apparatus, referred to below as LCD, iscoming into widespread use, the demand for a polarizing plate isincreasing rapidly. In general, a polarizing plate film includes apolarizing layer, exhibiting a light polarizing capability, and aprotective film(s) bonded to one or both surfaces thereof (see FIG.14(B)). As the material for the polarizing layer, polyvinyl alcohol,referred to below as PVA, is predominantly used. A polarizing film for apolarizing layer is formed by uniaxially stretching a PVA film, dyeingthe resulting polarizing film with iodine or a dichroic dye andcross-linking with a boron compound. The sequence of the uniaxialstretching and the dyeing may be inverted, if so desired. As theprotective film, mainly cellulose triacetate, referred to below as TAC,optically transparent and exhibiting only low birefringence, ispredominantly used. The polarizing plate is usually stretched in thelongitudinal direction, so that the axis of light absorption of thepolarizing film is approximately parallel to the longitudinal direction(see FIG. 14(A)). The polarizing plate film is provided with an adhesivelayer for bonding to the substrate. To the adhesive layer is bonded arelease film for protecting the adhesive layer from contaminants, suchas dust and dirt. The polarizing plate film, having the release filmbonded thereto, is furnished to the market, with a strip-shaped film,stretched in the longitudinal direction, in a roll form.

In a conventional LCD employing the TN (twisted nematic) liquid crystal,the polarizing plate is arranged with its axis of light transmissioninclined 45° relative to the longitudinal or transverse direction of animage frame. Thus, such a method consisting in bonding pieces of thepolarizing plate, obtained on pre-punching a roll of a polarizing platein a direction of 45° relative to the longitudinal direction of theroll, one by one to an LCD (see for example JP Patent KokaiJP-A-2002-23151) or such a method consisting in bonding a polarizingplate of a roll form to an LCD image surface as the longitudinal ortransverse direction of the LCD image surface is inclined at an angle of45° relatove to the longitudinal direction of the roll and subsequentlysevering the polarizing plate (see for example JP Patent KokaiJP-A-11-95028, FIG. 14(A)), have been devised. In an LCD employing a VA(vertical alignment) liquid crystal an LCD employing an IPS (in-planeswitching) liquid crystal, the axis of light transmission of thepolarizing plate is arranged in the longitudinal or transverse directionof the image frame and pieces of the polarizing plate are bonded one byone on the LCD.

In a conventional LCD, employing the TN (twisted nematic) crystal, sucha substrate on both sides of which have been bonded polarizing plates isused. Specifically, a first polarizing plate, having the axis of lighttransmission inclined 45° relative to the longitudinal or transversedirection of the image frame, is arranged on one surface of thesubstrate, whilst a second polarizing plate, having the axis of lighttransmission inclined 90° relative to the axis of transmission of thefirst polarizing plate, is arranged on the opposite surface thereof.

SUMMARY OF THE DISCLOSURE

However, with the method of bonding the pieces of the polarizing plateone-by-one on the LCD, these pieces of the polarizing plate need to bere-loaded, or the release film needs to be peeled off, directly beforebonding these pieces of the polarizing plates to the substrate, so thatthe process time cannot be shorter beyond a certain limit value. On theother hand, the piece of the polarizing plate is usually punched fromthe polarizing plate film in the roll form and hence tends to roll onitself with the consequence that it cannot be re-loaded or transportedwith an acceptable operating convenience.

With the method of bonding the polarizing plate to the LCD as thelongitudinal or transverse direction of the LCD image frame is inclined45° relative to the longitudinal direction of the roll, many unusableportions are produced near the roll end. In particular, there is raiseda problem that, if a large size polarizing plate is used in keeping upwith the increasing LCD image format, the yield is concomitantlylowered. The cut ends of the polarizing plate, not used for bonding, arehardly re-usable because plural sorts of the material are used incombination, as a result of which the amount of waste materials isincreased. This problem is presented common in case the pieces of thepolarizing plate are bonded one-by-one to the LCD.

Meanwhile, in the phase difference film, bonded in use to e.g., apolarizing plate forming the LCD with a view to optical compensation,such as prevention of coloration or enlarging the field of view, it isrequired to set the axis of orientation at various angles relative tothe axis of light transmission of the polarizing plate. Up to now, sucha system is used which consists in punching off the rim of a film, suchas a PET film, obtained on longitudinal or transverse uniaxialstretching, so that the axis of orientation is at a preset inclinationrelative to the sides of the polarized plate, thus lowering the yield,as in the case of the polarizing plate.

In the case of a composite film of an increased thickness, such as afilm obtained on bonding the phase difference film and the polarizingplate, cutting chips tend to be produced on severing. Moreover, if thecomposite film is severed directly before the bonding of the substrateand the composite film, the cutting chips tend to be introduced into thespace between the substrate and the composite film.

In the roll type polarizing plate film, the roll is increased in widthand weight, with the increasing size of the display image, with theresult that difficulties are met in exchanging the rolls.

Moreover, since it is difficult to visually recognize the axis oftransmission of the polarizing plate, it is difficult to exercisecontrol over the direction of transmission of the polarizing plate, sothat an error in the bonding direction is likely to be produced.Additionally, when bonding the pieces of the polarizing plate one by oneto the LCD, it is difficult to bond the chips of the polarizing platesimultaneously on both sides of the LCD, as the directions of the axesof light transmission of the chips of the polarizing plate are set todesign directions, because one lateral side of the LCD is supported bysuction in many cases.

It is noted that, when bonding the polarizing plates as the longitudinalor transverse direction of the LCD image surface is inclined 45°relative to the longitudinal direction of the roll, it is difficult tobond the polarizing plates simultaneously continuously to both substratesurfaces, as the axes of light transmission of the polarizing plates areset to the design directions, as described above, because a carrier isneeded to keep the angle of the LCD at a constant magnitude. Moreover,when bonding a polarizing plate to one substrate surface andsubsequently bonding another polarizing plate to the opposite substratesurface, angular adjustment is needed in re-loading the substrate fromthe first carrier to the second carrier, so that a complex mechanism isneeded for automation.

In addition, in the conventional polarizing plate bonding apparatus,there are occasions where the tacky surface in a roll portionresponsible for changing the film supply direction in the apparatusbecomes roughed when the film supply is halted in conjunction withcessation of the substrate transport, with the film thickness of theadhesive material becoming thicker or thinner to produce a so-calledstop mark, thus possibly deteriorating the display quality.

Thus there is much desired in the art.

It is a first object of the present invention to provide a method and anapparatus for bonding a polarizing plate which are superior in theoperating efficiency and in the yield of the polarizing plate.

It is a second object of the present invention to provide a method andan apparatus for bonding a polarizing plate in which a composite filmcomposed of the phase difference film and the polarizing plate bondedtogether may be produced at a high yield.

It is a third object of the present invention to provide a method and anapparatus for bonding a polarizing plate in which cutting chips are notliable to be intruded into a spacing between the substrate and the filmeven when the film is cut directly before bonding.

It is a fourth object of the present invention to provide a method andan apparatus for bonding a polarizing plate in which roll exchangeoperations may be carried out easily.

It is a fifth object of the present invention to provide a method and anapparatus for bonding a polarizing plate in which the polarizing platecan be bonded simultaneously to each substrate surface.

It is a sixth object of the present invention to provide a method and anapparatus for bonding a polarizing plate in which, when bonding thepolarizing plate to each substrate surface, control on the direction ofthe axis of light transmission of the polarizing plate can be exercisedeasily.

It is a seventh object of the present invention to provide a method andan apparatus for bonding a polarizing plate in which it is possible toprohibit stop marks on the adhesive film surface from being produced.

(First Solution)

In a first aspect, the present invention (first solution) provides apolarizing plate bonding apparatus comprising cutting means for cuttingat least a polarizing plate and an adhesive layer of a strip-shapedfilm, composed of a polarizing plate and a release film bonded to thepolarizing plate with interposition of the adhesive layer, so as toleave the release film uncut, when a forward end side pre-severed endface of the strip-shaped film perpendicular to a longitudinal directionof the strip-shaped film has traveled a length corresponding to a lengthof a substrate, to form a film piece, release film separating means forseparating the release film from the film piece severed by the cutting,and bonding means for bonding a tacky surface of the film piece freed ofthe release film to a mating position of the substrate so that a forwardend side end face of the transported substrate is parallel to thesevered end face of the film piece.

In a second aspect, the present invention (first solution) provides apolarizing plate bonding method comprising a cutting step of cutting atleast a polarizing plate and an adhesive layer of a strip-shaped film,composed of the polarizing plate and a release film bonded to thepolarizing plate, with interposition of the adhesive layer, when aforward end side severed end face of the strip-shaped film perpendicularto a longitudinal direction of the strip-shaped film has traveled alength corresponding to a length of a substrate, to form a film piece soas to leave the release film uncut, a release film separating step ofseparating the release film from the film piece severed by the cutting,and a bonding step of bonding a tacky surface of the film piece freed ofthe release film to a mating position of the substrate so that a forwardend side end face of the transported substrate is parallel to thesevered end face of the film piece.

In a third aspect, the present invention (first solution) provides apolarizing plate bonding method comprising a step of reeling out astrip-shaped film from a roll of the strip-shaped film of a presetwidth, composed of a polarizing plate and a release film bonded to thepolarizing plate, with interposition of the adhesive layer, and sendingthe film along a longitudinal direction thereof, a step of cutting atleast the polarizing plate and the adhesive layer of the strip-shapedfilm, each time a forward end side severed end face of the strip-shapedfilm perpendicular to a longitudinal direction of the strip-shaped filmhas traveled up to a length corresponding to a length of a substrate, ina direction perpendicular to the longitudinal direction of thestrip-shaped film, to form a film piece so as to leave the release filmuncut, a release film separating step of separating the release filmfrom the film piece severed by the cutting, a step of supplying the filmpiece, freed of the release film, in meeting with the position of thesubstrate transported, and a step of bonding the tacky surface of thesupplied film piece to a mating position of the substrate so that theforward end side end face of the transported substrate is parallel tothe severed end face of the film piece.

(Second Solution)

In one aspect, the present invention (second solution) provides apolarizing plate bonding apparatus comprising cutting means for cuttinga first strip-shaped film which is composed of a polarizing plate and arelease film bonded to the polarizing plate with interposition of anadhesive layer, and which is supplied from a front plate surface of asubstrate being transported, and a second strip-shaped film which iscomposed of a polarizing plate and a release film bonded to thepolarizing plate with interposition of an adhesive layer, and which issupplied from a reverse plate surface of the substrate beingtransported, when forward side pre-severed end faces along a proceedingdirection of the first and second strip-shaped films extending in adirection perpendicular to a longitudinal direction of the first andsecond strip-shaped films have traveled a distance corresponding to alength of the substrate, in such a manner that at least the polarizingplates and the adhesive layers of the first and second strip-shapedfilms are severed along a direction perpendicular to the longitudinaldirection, with the release film remaining uncut, a direction of an axisof light transmission of the polarizing plate of the second strip-shapedfilm being perpendicular to a direction of an axis of light transmissionof the polarizing plate of the first strip-shaped film when the firstand second strip-shaped films are bonded together on the release filmsides thereof, release film separating means for separating the releasefilms from a first film piece severed by the cutting of the firststrip-shaped film and a second film piece severed by the cutting of thefirst strip-shaped film, and bonding means for bonding a tacky surfaceof the first film piece, freed of the release film, to a mating frontside plate surface of the substrate so that the severed end face of thefirst film piece is parallel to the forward side end face along atransporting direction of the substrate, and for bonding a tacky surfaceof the second film piece, freed of the release film, to a mating reverseside plate surface of the substrate so that the severed end face of thesecond film piece is parallel to the forward side end face along thetransporting direction of the substrate.

In a second aspect, the present invention (second solution) provides apolarizing plate bonding apparatus comprising release film separatingmeans for separating a release film from a first strip-shaped film,comprised of a polarizing plate and a release film bonded to thepolarizing plate with interposition of an adhesive layer, the firststrip-shaped film being supplied from a front plate surface side of asubstrate being transported, and from a second strip-shaped film,comprised of a polarizing plate and a release film bonded to thepolarizing plate with interposition of an adhesive layer, the secondstrip-shaped film being supplied from a reverse plate surface side ofthe substrate being transported, with a direction of an axis of lighttransmission of the polarizing plate of the second strip-shaped filmbeing perpendicular to a direction of an axis of light transmission ofthe polarizing plate of the first strip-shaped film when the releasefilm of the second strip-shaped film is bonded to the release film ofthe first strip-shaped film, bonding means for bonding a tacky surfaceof the first strip-shaped film, freed of the release film, to a matingfront plate surface of the substrate so that a proceeding direction ofthe first strip-shaped film coincides with the transport direction ofthe substrate, and for bonding a tacky surface of the secondstrip-shaped film, freed of the release film, to a mating reverse platesurface of the substrate so that the proceeding direction of the secondstrip-shaped film coincides with the transport direction of thesubstrate, and cutting means for cutting the first and secondstrip-shaped films, bonded to both surfaces of the substrate by thebonding means, in a direction parallel to the forward end face or therear end face along the transport direction of the substrate.

In a third aspect, the present invention (second solution) provides apolarizing plate bonding apparatus comprising first transport means fortransporting the substrate with one end surface thereof perpendicular tothe proceeding direction, first bonding means for bonding a tackysurface of a first film piece, having a polarizing plate, to a matingplate surface piece of the substrate so that the pre-severed end face ofthe first film piece is parallel to an end face along the proceedingdirection of the substrate transported by the first transporting means,second transporting means for transporting the substrate transported bythe first transporting means along a direction perpendicular to thetransport direction by the first transport means, and second bondingmeans for bonding a tacky surface of a second film piece to a matingplate surface of the substrate opposite to the surface thereof to whichhas been bonded the first film piece, so that the pre-severed end faceof the second film piece is parallel to the end face along theproceeding direction of the substrate transported by the secondtransport means. The second film piece has a polarizing plate, and issupplied from a plate surface opposite to the surface bonded to thefirst film piece of the substrate transported by the second transportmeans. The direction of the axis of light transmission of the polarizingplate of the second film piece is perpendicular to the direction of theaxis of light transmission of the polarizing plate of the first filmpiece when the tacky surface of the polarizing plate of the second filmpiece is bonded to the tacky surface of the polarizing plate of thefirst film piece.

In a fourth aspect, the present invention (second solution) provides apolarizing plate bonding apparatus comprising first transport means fortransporting a substrate with an end face thereof perpendicular to theproceeding direction, first cutting means for cutting a tacky surface ofa first strip-shaped film having a polarizing plate, along a directionparallel to the forward or rear end face along the transport directionof the substrate so that the proceeding direction of the firststrip-shaped film is parallel to the end face along the proceedingdirection of the substrate transported by the first transport means,second transport means for transporting the substrate transported by thefirst transport means along a direction perpendicular to the transportdirection by the first transport means, and second cutting means forcutting along a direction parallel to the forward or rear end face alongthe transport direction of the substrate. To a surface of this substrateopposite to the surface thereof bonded to the film piece of the firststrip-shaped film is bonded a tacky surface of a second strip-shapedfilm, so that the severed end face of the second strip-shaped film isparallel to the end face along the proceeding direction of the substratetransported by the second transport means. The second strip-shaped filmhas a polarizing plate and being supplied from a plate surface side ofthe substrate transported by the second transport means which isopposite to the substrate surface bonded to the first film piece. Theaxis of light transmission of the polarizing plate of the secondstrip-shaped film is perpendicular to the axis of light transmission ofthe polarizing plate of the first strip-shaped film when the releasefilm side of the second strip-shaped film is bonded to the release filmside of the first strip-shaped film.

In a fifth aspect, the present invention (second solution) provides amethod for bonding a polarizing plate comprising a step of cutting afirst strip-shaped film including a polarizing plate and a release filmbonded thereto with interposition of an adhesive layer, and a secondstrip-shaped film including a polarizing plate and a release film bondedthereto with interposition of an adhesive layer, when the pre-severedend faces of the first and second strip-shaped films along theproceeding direction thereof perpendicular to the longitudinal directionhave traveled a distance corresponding to the length of a substrate, sothat at least the polarizing plates and the adhesive layers of the firstand second strip-shaped films are severed along a directionperpendicular to the longitudinal direction, with the exception of therelease layer which remains uncut, a step of separating the releasefilms of the first and second strip-shaped films, severed by the cuttingof the first and second strip-shaped films, and a step of bonding thetacky surface of the first film piece, freed of the release film, to amating front side surface of the first strip-shaped film, so that thesevered end face of the first film piece is parallel to the forward endface along the transport direction of the substrate, and bonding thetacky surface of the second film piece, freed of the release film, to amating reverse side surface of the second strip-shaped film, so that thesevered end face of the second film piece is parallel to the forward endface along the transport direction of the substrate. The firststrip-shaped film is supplied from the front plate surface side ofsubstrate being transported, while the second strip-shaped film issupplied from the reverse plate surface side of a substrate beingtransported. The direction of the axis of light transmission of thepolarizing plate of the second strip-shaped film is perpendicular to thedirection of the axis of light transmission of the polarizing plate ofthe first strip-shaped film when the release film of the secondstrip-shaped film is bonded to the release film of the firststrip-shaped film, a step of separating the release films of the firstand second strip-shaped films, severed by the cutting of the first andsecond strip-shaped films, and a step of bonding the tacky surface ofthe first film piece, freed of the release film, to a mating front sidesurface of the first strip-shaped film, so that the severed end face ofthe first film piece is parallel to the forward end face along thetransport direction of the substrate, and bonding the tacky surface ofthe second film piece, freed of the release film, to a mating reverseside surface of the second strip-shaped film, so that the severed endface of the second film piece is parallel to the forward end face alongthe transport direction of the substrate.

In a sixth aspect, the present invention (second solution) provides amethod for bonding a polarizing plate comprising a step of separating arelease film from each of a first strip-shaped film and a secondstrip-shaped film, the first strip-shaped film including a polarizingplate and the release film bonded thereto with interposition of anadhesive layer, the first strip-shaped film being supplied from thefront plate surface side of a substrate being transported; the secondstrip-shaped film including a polarizing plate and the release filmbonded thereto with interposition of an adhesive layer, the secondstrip-shaped film being supplied from the reverse plate surface side ofa substrate being transported; the direction of the axis of lighttransmission of the polarizing plate of the second strip-shaped filmbeing perpendicular to the direction of the axis of light transmissionof the polarizing plate of the first strip-shaped film when the releasefilm of the second strip-shaped film is bonded to the release film ofthe first strip-shaped film, a bonding step of bonding the tacky surfaceof the first strip-shaped film, freed of the release film, to a matingfront plate surface of the substrate so that the proceeding direction ofthe first strip-shaped film coincides with the transport direction ofthe substrate, and bonding the tacky surface of the second strip-shapedfilm, freed of the release film, to a mating reverse plate surface ofthe substrate so that the proceeding direction of the secondstrip-shaped film coincides with the transport direction of thesubstrate, and a cutting step of severing the first strip-shaped filmand the second strip-shaped film, bonded to both surfaces of thesubstrate by the bonding means, along the direction parallel to theforward or rear end faces along the transport direction of thesubstrate.

In a seventh aspect, the present invention (second solution) provides amethod for bonding a polarizing plate comprising a step of transportinga substrate with one end face of the substrate perpendicular to theproceeding direction, a step of bonding a tacky surface of a first filmpiece, having a polarizing plate, to a mating plate surface piece of thesubstrate so that the severed end face of the first film piece isparallel to the forward side end face along the transport direction ofthe substrate, a step of changing the direction of transport of thetransported substrate and transporting the substrate along the sochanged direction, and a step of bonding a tacky surface of the secondfilm piece to a plate surface of the substrate opposite to the substratesurface to which the first film piece has been bonded, so that thesevered end face of the second film piece is parallel to a forward endface along the transport direction of the substrate; the second filmpiece including a polarizing plate and being supplied from the platesurface of the substrate opposite to the substrate surface to which thefirst film piece has been bonded; the direction of the axis of lighttransmission of the polarizing plate of the second strip-shaped filmbeing perpendicular to the direction of the axis of light transmissionof the polarizing plate of the first strip-shaped film when the tackysurface of the polarizing plate is bonded to the tacky surface of thefirst strip-shaped film

In an eighth aspect, the present invention (second solution) provides amethod for bonding a polarizing plate comprising a step of transportinga substrate with one end face of the substrate perpendicular to theproceeding direction, a step of cutting a tacky surface of a firststrip-shaped film, having a polarizing plate, along a direction parallelto the forward or rear side end face along the transport direction ofthe substrate, bonded to one mating plate surface, so that theproceeding direction of the first strip-shaped film is parallel to theforward side end face along the transport direction of the substrate, asecond transport step of changing the direction of transport of thetransported substrate and transporting the substrate along the sochanged direction, and a step of cutting along a direction parallel tothe forward or rear end face along the transport direction of thesubstrate, to a plate surface of which opposite to the plate surfacecarrying the film piece of the first strip-shaped film has been bonded atacky surface of the second strip-shaped film, so that the severed endface of the second strip-shaped film is parallel to the end face alongthe proceeding direction of the substrate. The second strip-shaped filmhas a polarizing plate and is supplied from a plate surface side of thesubstrate transported by the second transport means which is opposite tothe substrate surface bonded to the first film piece. The axis of lighttransmission of the polarizing plate of the second strip-shaped film isperpendicular to the axis of light transmission of the polarizing plateof said first strip-shaped film when the release film side of the secondstrip-shaped film is bonded to the release film side of the firststrip-shaped film.

(Third Solution)

In a first aspect, the present invention (third solution) provides apolarizing plate bonding apparatus comprising release film separatingmeans for separating a release film from a strip-shaped film comprisedof a polarizing plate and the release film bonded thereto withinterposition of an adhesive layer, the strip-shaped film being suppliedfrom one plate surface of a substrate being transported, bonding meansfor bonding a tacky surface of the strip-shaped film, freed of therelease film, so that the proceeding direction of the strip-shaped filmcoincides with the transport direction of the substrate, and cuttingmeans for cutting the strip-shaped film, bonded to one surface of thesubstrate by the bonding means, along a direction parallel to a forwardor rear end face along the transport direction of the substrate.

In a second aspect, the present invention (third solution) provides amethod for bonding a polarizing plate comprising

a step of separating a release film from a strip-shaped film comprisedof a polarizing plate and the release film bonded thereto withinterposition of an adhesive layer, the strip-shaped film being suppliedfrom one plate surface of a substrate being transported;

a step of bonding a tacky surface of the strip-shaped film, freed of therelease film, to a mating plate surface of the substrate, so that theproceeding direction of the strip-shaped film coincides with thetransport direction of the substrate; and

a step of severing the strip-shaped film, bonded to one surface of thesubstrate by the bonding, along a direction parallel to the forward orrear end face along the transport direction of the substrate.

(Fourth Solution)

In a first aspect, the present invention (fourth solution) provides apolarizing plate bonding apparatus comprising release film separatingmeans for separating a release film from a strip-shaped film comprisedof a polarizing plate and the release film bonded thereto withinterposition of an adhesive layer, the strip-shaped film being suppliedfrom one plate surface of the substrate transported, in a state suchthat at least the polarizing plate and the adhesive film are severed sothat at least one side of a rectangle of the strip-shaped film in a filmsurface area registering with the substrate is perpendicular to thelongitudinal direction of the film, with the release film remaininguncut, bonding means for bonding at least a tacky surface within therectangle of the strip-shaped film to a mating plate surface of thesubstrate, so that the proceeding direction of the strip-shaped filmcoincides with the transport direction of the substrate, and selvedgeseparating means for separating selvedges of the strip-shaped film otherthan the inner area of the rectangle from the substrate.

In a second aspect, the present invention (fourth solution) provides apolarizing plate bonding apparatus comprising cutting means for cuttingat least a polarizing plate and an adhesive layer of a strip-shapedfilm, comprised of the polarizing plate and a release layer bondedthereto with interposition of an adhesive layer, so as to leave therelease film uncut, the strip-shaped film being supplied from one platesurface side of a substrate being transported, so that at least one sideof a rectangle in a film surface area mating with the substrate isperpendicular to the longitudinal direction of the film, release filmseparating means for separating the release film from the strip-shapedfilm cut by the cutting means, bonding means for bonding a tacky surfaceof an inner area of the rectangle of the strip-shaped film, freed of therelease film, to a mating plate surface of the substrate, so that theproceeding direction of the strip-shaped film coincides with thetransport direction of the substrate, and selvedge separating means forseparating a selvedge of the strip-shaped film other than the inner areaof the rectangle from the substrate.

In a third aspect, the present invention (fourth solution) provides apolarizing plate bonding apparatus comprising release film separatingmeans for separating a release film from a strip-shaped film, comprisedof a polarizing plate and the release layer bonded thereto withinterposition of an adhesive layer, the strip-shaped film being suppliedfrom one plate surface of a substrate being transported, bonding meansfor bonding at least a tacky surface of the strip-shaped film, freed ofthe release film, to a mating plate surface of the substrate, so thatthe proceeding direction of the strip-shaped film coincides with thetransport direction of the substrate, cutting means for cutting thestrip-shaped film within an area in which the strip-shaped film has beenbonded to the substrate, within a rectangle corresponding to thesubstrate, so that at least one side of the rectangle is perpendicularto the longitudinal direction, and selvedge separating means forseparating selvedges of the strip-shaped film other than the inner areaof the rectangle from the substrate.

In a fourth aspect, the present invention (fourth solution) provides amethod for bonding a polarizing plate comprising a step of separating arelease film from a strip-shaped film comprised of a polarizing plateand the release film bonded thereto with interposition of an adhesivelayer and supplied from one plate surface of a substrate beingtransported, in a state in which at least the polarizing plate and therelease film are pre-severed, with the release film remaining uncut, sothat at least one side of a rectangle corresponding in profile to thesubstrate in an area of a film surface is perpendicular to thelongitudinal direction of the film, a step of bonding a tacky surface ofan inner portion of the rectangle of the strip-shaped film, freed of therelease film, to a mating plate surface of the substrate, so that theproceeding direction of the strip-shaped film coincides with thetransport direction of the substrate, and a step of separating aselvedge of the strip-shaped film other than the inner portion of therectangle, from the substrate.

In a fifth aspect, the present invention (fourth solution) provides amethod for bonding a polarizing plate comprising a step of severing atleast a polarizing plate and an adhesive layer from a strip-shaped film,comprised of a polarizing plate and the release film bonded thereto withinterposition of an adhesive film, and supplied from one plate surfaceof a substrate being transported, with the release film remaining uncut,so that at least one side of a rectangle corresponding in profile to thesubstrate in an area of a film surface is perpendicular to thelongitudinal direction of the film, a step of separating the releasefilm from the strip-shaped film severed in the cutting step, a step ofbonding at least a tacky surface in an inner portion of the rectangle ofthe strip-shaped film, freed of the release film, to a mating platesurface of the substrate, so that the proceeding direction of thestrip-shaped film coincides with the transport direction of thesubstrate, and a step of separating a selvedge of the strip-shaped filmother than the inner portion of the rectangle, from the substrate.

In a sixth aspect, the present invention (fourth solution) provides amethod for bonding a polarizing plate comprising a step of separating arelease film from a strip-shaped film comprised of a polarizing plateand the release film bonded thereto with interposition of an adhesivefilm, the strip-shaped film being supplied from one plate surface of asubstrate transported, a step of bonding at least a tacky surface of thestrip-shaped film, freed of the release film, to a mating plate surfaceof the substrate, so that the proceeding direction of the strip-shapedfilm coincides with the transport direction of the substrate, a step ofcutting the strip-shaped film within an area in which the strip-shapedfilm is bonded to the substrate, within a rectangle mating in profile tothe substrate, so that at least one side of the rectangle isperpendicular to the longitudinal direction of the film, and a step ofseparating a selvedge of the strip-shaped film other than the innerportion of the rectangle from the substrate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic side view showing the structure of a strip-shapedfilm used in an embodiment of a polarizing plate bonding apparatus ofthe present invention (first solution).

FIGS. 2(A) and (B) are a plan view and a cross-sectional view,respectively, showing the structure of a strip-shaped film used in thepolarizing plate bonding apparatus of the present invention (firstsolution).

FIG. 3 is a schematic side view showing the structure of a first releasefilm separating means in the polarizing plate bonding apparatus of thepresent invention (first solution).

FIG. 4 is a schematic side view showing the structure of a secondrelease film separating means in the polarizing plate bonding apparatusof the present invention (first solution).

FIG. 5 is a schematic side view showing the structure of a third releasefilm separating means in the polarizing plate bonding apparatus of thepresent invention (first solution).

FIG. 6 is a schematic side view showing the structure of an improvedmodification of the third release film separating means in thepolarizing plate bonding apparatus of the present invention (firstsolution).

FIG. 7 is a schematic side view showing the structure of an improvedmodification of the third release film separating means in thepolarizing plate bonding apparatus of the present invention (firstsolution).

FIG. 8 is a schematic side view showing the structure of a fourthrelease film separating means in the polarizing plate bonding apparatusof the present invention (first solution).

FIG. 9 is a schematic side view showing the structure of a first bondingmeans in the polarizing plate bonding apparatus of the present invention(first solution).

FIG. 10 is a schematic side view showing the structure of a secondbonding means in the polarizing plate bonding apparatus of the presentinvention (first solution).

FIG. 11 is a schematic side view showing the structure of a secondbonding means in the polarizing plate bonding apparatus of the presentinvention (first solution).

FIG. 12 is a schematic view showing a first processing instance of asubstrate bonded by the polarizing plate bonding apparatus of thepresent invention (first solution).

FIG. 13 is a schematic side view showing the structure of a strip-shapedfilm used in a modified embodiment of a polarizing plate bondingapparatus of the present invention (first solution).

FIGS. 14(A) and (B) are a plan view and a cross-sectional view,respectively, showing the structure of a strip-shaped film used in aconventional polarizing plate bonding apparatus.

FIG. 15 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to an embodiment 1 of thepresent invention (second solution).

FIGS. 16(A) and (B) are a plan view and a cross-sectional view,respectively, showing the structure of a strip-shaped film used in apolarizing plate bonding apparatus according to the embodiment 1 of thepresent invention (second solution).

FIG. 17 is a developed perspective view schematically showing therelationship between the substrate and the stretching direction of thepolarizing plate bonded to each substrate surface by the polarizingplate bonding apparatus according to the embodiment 1 of the presentinvention (second solution).

FIG. 18 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to the embodiment 2 of thepresent invention (second solution).

FIG. 19 is a developed perspective view schematically showing therelationship between the substrate and the stretching direction of thepolarizing plate bonded to each substrate surface by the polarizingplate bonding apparatus according to the embodiment 1 of the presentinvention (second solution).

FIG. 20 is a perspective view schematically showing the structure of thepolarizing plate bonding apparatus according to an embodiment 3 of thepresent invention (second solution).

FIG. 21 is a plan view schematically showing the structure of thepolarizing plate bonding apparatus according to the embodiment 3 of thepresent invention (second solution).

FIG. 22 is a side view schematically showing the structure of a firsttransport unit of the polarizing plate bonding apparatus according to anembodiment 3 of the present invention (second solution).

FIG. 23 is a side view schematically showing the structure of a secondtransport unit of the polarizing plate bonding apparatus according tothe embodiment 3 of the present invention (second solution).

FIG. 24 is a side view schematically showing the structure of a firsttransport unit of the polarizing plate bonding apparatus according to anembodiment 4 of the present invention (second solution).

FIG. 25 is a side view schematically showing the structure of a secondtransport unit of the polarizing plate bonding apparatus according tothe embodiment 4 of the present invention (second solution).

FIG. 26 is a side view and a plan view schematically showing thestructure of a polarizing plate bonding apparatus according to theembodiment 1 of the present invention (third solution).

FIG. 27 is a plan view and a cross-sectional view showing the structureof a strip-shaped film used in the polarizing plate bonding apparatusaccording to the embodiment 1 of the present invention (third solution).

FIG. 28 is a side view schematically showing the operation of cuttingmeans of the polarizing plate bonding apparatus according to theembodiment 1 of the present invention (third solution).

FIG. 29 is a side view and a plan view schematically showing thestructure of a polarizing plate bonding apparatus according to theembodiment 2 of the present invention (third solution).

FIG. 30 is a side view schematically showing the operation of cuttingmeans of the polarizing plate bonding apparatus according to theembodiment 2 of the present invention (third solution).

FIG. 31 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to the embodiment 3 of thepresent invention (third solution).

FIG. 32 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to the embodiment 1 of thepresent invention (fourth solution).

FIG. 33 is a plan view and a cross-sectional view showing the structureof a polarizing plate used in the polarizing plate bonding apparatusaccording to the embodiment 1 of the present invention (fourthsolution).

FIG. 34 is a perspective view schematically showing the state of bondingand selvedge separation in the polarizing plate bonding apparatusaccording to the embodiment 1 of the present invention (fourthsolution).

FIG. 35 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to the embodiment 2 of thepresent invention (fourth solution).

FIG. 36 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to the embodiment 3 of thepresent invention (fourth solution).

FIG. 37 is a perspective view schematically showing the state of bondingand selvedge separation in the polarizing plate bonding apparatusaccording to the embodiment 3 of the present invention (fourthsolution).

FIG. 38 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to the embodiment 4 of thepresent invention (fourth solution).

FIG. 39 is a side view schematically showing the structure of apolarizing plate bonding apparatus according to an embodiment 5 of thepresent invention (fourth solution).

PREFERRED EMBODIMENTS OF THE INVENTION

[Embodiment of the First Solution]

Referring to the drawings, certain preferred embodiments of the presentinvention (first solution) are explained in detail. FIG. 1 is a sideview schematically showing the structure of a polarizing plate bondingapparatus according to an embodiment of the present invention (firstsolution). FIG. 2 is a plan view and a cross-sectional view showing aband-shaped film used in a polarizing plate bonding device according toan embodiment of the present invention (first solution).

FIG. 1 shows a polarizing plate bonding apparatus 101 for bonding apolarizing plate to a substrate. The polarizing plate bonding apparatus101 includes a cutting means 102 for cutting at least a polarizing plateand an adhesive layer of a strip-shaped film 110, composed of thepolarizing plate to which a release film 111 is bonded with the adhesivelayer therebetween, in the direction orthogonal to the longitudinaldirection of the strip-shaped film 110, and a release film 111 bonded tothe polarizing plate with interposition of the adhesive layer, so as toleave the release film 111 uncut, when a forward-facing severed end ofthe strip-shaped film perpendicular to the longitudinal direction of thestrip-shaped film has traveled a length corresponding to the length of asubstrate 120, a release film separating means 103 for separating therelease film 111 from a film piece 119 severed by the cutting, andbonding means 104, 105 for bonding the tacky surface of the film piece119 freed of the release film 111 to a corresponding position of thesubstrate 120 so that the forward-facing end of the substrate 120 isparallel to the severed end of the film piece 119, such that the filmpieces of the polarizing plate can be bonded to the substratecontinuously automatically to raise the yield of the polarizing plate to100%.

A strip-shaped film 110 according to the present invention (firstsolution) is a film comprised of a polarizing plate and a release film111 bonded thereto via an adhesive layer, and may, for example, acircular polarizing film comprised of a polarizing plate 116 and a phasedifference film 113 bonded together as shown in FIG. 2(B). In caseswhere it is used for an LCD for TN liquid crystal, the polarizing plate116 has its direction of the axis of transmission oriented obliquelywith respect to the longitudinal direction of the film. The angle ofinclination between the longitudinal direction of the film and the axisof transmission is preferably not less than 20° and not more than 70°and more preferably not less than 40° and not more than 50°. It isusually 45° (see FIG. 2(A)). As to the method for producing this sort ofthe polarizing plate, the JP Patent Kokai JP-A-2002-86554 should bereferred. Preferably, protective films 115, 117 are bonded to bothsurfaces of the polarizing plate 116. This polarizing plate 116 is sucha polarizing plate stretched obliquely with respect to the longitudinaldirection of the film and hence is termed below an “obliquely stretchedpolarizing plate”. With use of the obliquely stretched polarizing plate116, continuous film supply becomes possible. In the case of a circularpolarizing film, composed of the obliquely stretched polarizing plate116 (protective film 115) and a phase difference film 113, bondedthereto via an adhesive layer 114, the phase difference film 113 as usedpreferably has an axis of orientation perpendicular or parallel to thelongitudinal direction of the film. By so doing, the circular polarizingfilm can be continuously supplied. The polarizing plate 116 is of athickness on the order of for example 5 through 100 μm. The width of thepolarizing plate 116 is suitably selected depending on the size of thesubstrate to which it is bonded. It is sufficient that the adhesives112, 114 are ordinary adhesives used for bonding the substrate and anoptical film to each other, such as an acrylic-, polyurethane-, epoxy-or rubber-based adhesive. The release film 111 is of a release materialwhich may be a routine release material used for an optical film, suchas a polyethylene terephthalate film or a polyester film. On the surfaceof the polarizing plate 116 opposite to the surface thereof bonded tothe release film 111, an inserting paper sheet 118 may be bonded forprotecting the film surface from possible grazing. The strip-shaped film110 is preferably reeled out from a payout (real-out) roll 106 (see FIG.1). Meanwhile, in cases where the polarizing plate 116 is used for anLCD for VA liquid crystal or a liquid crystal for an IPS system, thepolarizing plate 116 may be used, the direction of the axis of lighttransmission of which is oriented parallel or at right angles to thelongitudinal direction of the film.

A substrate 120 is a flat plate shaped member, such as a glass substrateor a plastic substrate, used for a display apparatus, such as an LCD ora plasma display apparatus. The substrate 120 may be a substrate onwhich component parts, such as liquid crystal cell or electrode, arepreviously formed. The substrate 120 may be substantially quadrilateral,such as a square or a rectangle (see FIGS. 1 and 2(A)).

The cutting means 102 may be exemplified by a push-cut or a dicing typecutter, used for ordinary cutting of an optical film, provided with, forexample, a cutter edge, a cylinder driving the cutter edge, and with alower dead point adjustment member for adjusting the lower dead point ofthe cutter edge. By adjusting the lower dead point to not more than 0.5times as thick as the release film 111, the other layers of thestrip-shaped film 110, such as the polarizing plate or the adhesivelayer, may be cut in a direction perpendicular to the longitudinaldirection of the film (see FIG. 1). In cases where the lower dead pointis more than 0.5 times, the other layers of the strip-shaped film 110,such as the polarizing plate or the adhesive layer, may remain uncut,whereas, in cases where the lower dead point is less than 0 times, eventhe release film 111 may be cut.

The release film separating means 103 is a means (roll in FIG. 1) forseparating the release film from the strip-shaped film (film piece), andmay, for example, be configured as follows:

FIG. 3 is a side view schematically showing the structure of a firstrelease film separating means in a polarizing plate bonding apparatusaccording to an embodiment of the present invention (first solution). Asthis first release film separating means, an edge member 131 having arounded edge at the foremost part thereof is used (see FIG. 3). With anedge end of the edge member 131 directed in the direction of travel thefilm piece 119, one blade surface of the edge member 131 is abuttedagainst the surface of the release film 111 to cause the edge end tofold only the release film 111 towards the other blade surface of theedge member 131. The film piece 119, now freed of the release film 111,is allowed to proceed in the forward direction, in order to take up onlythe release film 111.

FIG. 4 depicts a side view schematically showing the structure of asecond release film separating means in the polarizing plate bondingapparatus according to one embodiment of the present invention (firstsolution). As the second release film separating means, a suctionconveyor 132 is used, in which an endless belt 136, provided with airvent holes, is placed on pulleys 134, 135 provided on both ends of aframe, not shown, and air is sucked from an inner side of the belt 136by a suction table 133 in a flattened area of the belt 136 to suck thefilm piece 119 on the belt 136 to transport the so sucked film piece(see FIG. 4). The suction area on the belt 136 of the suction conveyor132 is abutted against the surface of the release film 111 of the filmpiece 119. The transport side pulley 134 causes only the release film111 to be folded back towards the return path of the belt 136 to take uponly the release film 111 as the film piece 119 freed of the releasefilm 111 is allowed to travel in the forward direction. The transportside pulley 134 operates as a separating roll.

FIG. 5 is a side view schematically showing the structure of a thirdrelease film separating means in the polarizing plate bonding apparatusin an embodiment of the present invention (first solution). FIG. 6depicts a side view showing the structure of an improved third releasefilm separating means in the polarizing plate bonding apparatusembodying the present invention (first solution). FIG. 7 depicts a sideview showing the structure of a further improved third release filmseparating means in the polarizing plate bonding apparatus embodying thepresent invention (first solution). As the third release film separatingmeans, a suction conveyor 137 again is used. However, the suction areaon the belt of the suction conveyor 137 is abutted on the surface of afilm piece 119 opposite to a release film 111, and a separating roll 142is abutted on the surface of the release film 111 of the film piece 119in an abutment area to the belt 141. Then the film piece 119 is suckedand transported by the suction conveyor 137, only the release film 111is folded back by the separating roll 142, and the film piece 119, nowfreed of the release film 111, continues its travel in the forwarddirection to take up only the release film 111 (see FIG. 5). In thepresent embodiments, the suction conveyor 137 operates as a film piecesupplying means for supplying the film piece 119. Meanwhile, the filmpiece 119, the separating roll 142 and the suction conveyor 137 may beprovided not on the upper surface but on the lower surface of thesubstrate 120 (see FIG. 6). The separating roll 142 may be provided witha nip function for thrusting against the belt 141. In cases where theseparating roll 142 is abutted against the transport side pulley 139 ofthe suction conveyor 137, no suction operation is needed (see FIG. 7).

FIG. 8 is a side view schematically showing the structure of a fourthrelease film separating means in the polarizing plate bonding apparatusin an embodiment of the present invention (first solution). As thefourth release film separating means, a suction drum 146 evacuating adrum member having air vent holes from its inner side by suction forsucking the film piece 119 onto the cylindrical surface of the drummember and for transporting the so sucked film piece, is used (see FIG.8). A drive of a separating roll 147, including a drive for supplyingthe film piece 119, and a drive of a suction drum 146 are controlled tocause rotation of the suction drum as the surface opposite to the tackysurface of the film piece 119, freed of the release film 111 by theseparating roll 147, is attracted to the surface of the suction drum 146to transport the film piece 119. The supply of the film piece 119 ishalted for a preset time as the suction drum 146 continues its rotation.After a preset time, the next film piece 119′ is supplied. This sequenceof operations is repeated (see FIG. 8). The suction drum 146 is apressure roll as well and, if used with a receiving roll 148, operatesas a bonding means. This operation is convenient in cases where the filmpiece with a surface area smaller than the plate surface area of thesubstrate is bonded to the substrate at a preset spacing from thesubstrate edge (so-called bonding with a margin). Meanwhile, in caseswhere the length in the forward direction of the film piece 119 iscoincident with the length in the forward direction of the substrate,plural film pieces 119 may be supplied to the suction drum 146 insuccession, without providing a gap between the film pieces, as thedriving of the separating roll 147 is synchronized with the driving ofthe suction drum 146 (that is, without halting the driving of theseparating roll 147).

Meanwhile, the release film 111 separated from the strip-shaped film 110(film piece 119) may be taken up on the take-up roll 107 for recovery(see FIG. 1).

The bonding means 104, 105 represent means for bonding the tacky surfaceof the film piece 119, freed of the release film 111, to a matingposition on the substrate, so that the severed side of the film piece119 is parallel to the end face in the forward direction of thesubstrate (see FIG. 1). The following means may, for example, be used.

FIG. 9 is a side view schematically showing the structure of a firstbonding means in a polarizing plate bonding apparatus according to anembodiment of the present invention (first solution). As the firstbonding means, an oscillating type suction table 151 for sucking andholding the substrate on the upper table surface by sucking andevacuating from the inner side of the table for transporting the sosucked and held substrate, and a pressure bonding roll 152 for bondingthe film piece 119 on the substrate by pressuring towards theoscillating type suction table 151 (see FIG. 9), are used. As theoscillating type suction table 151, which has sucked and held thesubstrate 120, is moved, the film piece 119, freed of the release film111, is pressed by the pressure bonding roll 152 from the upper surfaceside of the substrate 120 for bonding the film piece 119 to a presetlocation of the substrate 120.

FIG. 10 is a side view schematically showing the structure of a secondbonding means in a polarizing plate bonding apparatus according to anembodiment of the present invention (first solution). As the secondbonding means, an oscillating type suction table 154 similar to theoscillating type suction table used in the first bonding means, apressure bonding table 155 similar to the pressure bonding table used inthe first bonding means, and a stationary type suction table 157 forsucking the film piece 119, are used (see FIG. 10). As the oscillatingtype suction table 154, which has sucked and held the substrate 120, ismoved, the surface opposite to the tacky surface of the film piece 119,freed of the release film 111, is sucked by the stationary type suctiontable 157, and slid. The film piece 119, thus slid, is pressed by thepressure bonding table 155 from the upper side of the substrate 120 forbonding the film piece 119 onto a preset location on the substrate 120.

FIG. 11 is a side view schematically showing the structure of a thirdbonding means in a polarizing plate bonding apparatus according to anembodiment of the present invention (first solution). As the thirdbonding means, a roller conveyor 158 for horizontally transporting thesubstrate 120 on an array of plural rolls, a pressure bonding roll 159similar to the pressure bonding roll used in the first bonding means, areceiving roll 160 for transporting the substrate 120, transportedthereto, and for sustaining the pressure from the pressure bonding roll159 from the under the roll 159, and a stationary type suction table 162similar to that used in the second bonding means, are used (see FIG.11). The substrate 120 is transported by the roller conveyor 158 to aspacing between the pressure bonding roll 159 and the receiving roll160, the film piece 119, freed of the release film 111, is slid as thesurface of the film piece opposite to its tacky surface is sucked by thestationary type suction table 162, and the so slid film piece 119 ispressed by the pressure bonding roll 159 from the upper surface of thesubstrate 120 to bond the film piece 119 to a preset location on thesubstrate 120.

Meanwhile, the pressure bonding rolls (152 of FIG. 9, 155 of FIG. 10 and159 of FIG. 11) and the receiving rolls (148 of FIG. 8 and 160 of FIG.11) are rubber rolls or metal rolls. The rubber roll is preferablyformed of rubber with a hardness of 60 to 80°. One of the pressurebonding rolls or the receiving rolls is preferably a rubber roll. Incases where two rolls are used, as shown in FIG. 11, a set of two rubberrolls of hardness of 60 to 80° or a set of a rubber roll of hardness of60 to 80° and a metal roll is preferably used. The nip pressure of thetwo rolls at the time of bonding is preferably a linear pressure notmore than 1 kg/cm. In cases where the hardness is less than 60°,pressure variations and hence pressure bonding variations are produced.With the hardness exceeding 80°, the substrate or the film tends to bedamaged. Moreover, regarding the nip pressure, the linear pressureexceeding 1 kg/cm tends to damage the substrate or the film.

Next, a processing instance is explained. A film piece 119 may be bondedto each substrate 120 delivered to directly give a bonded substrate (seeFIG. 12).

[Embodiment of the Second Solution]

A first embodiment of the present invention (second solution) is nowexplained with reference to the drawings. FIG. 15 is a side viewschematically showing the structure of a polarizing plate bondingapparatus of an embodiment 1 of the present invention (second solution).FIG. 16 is a plan view (A) and a cross-sectional view (B) showing thestructure of a strip-shaped film used in the polarizing plate bondingapparatus of the embodiment 1 of the present invention (secondsolution). FIG. 17 is a developed perspective view schematically showingthe relationship between the substrate and the stretching direction ofthe polarizing plate bonded to each substrate surface by the polarizingplate bonding apparatus of the embodiment 1 of the present invention(second solution).

A polarizing plate bonding apparatus 230 according to the embodiment 1of the second solution, shown in FIG. 15, includes a first cutting means231A, a second cutting means 231B, a first release film separating means232A, a second release film separating means 232B, and a bonding means233. The first cutting means 231A severs at least a polarizing plate andan adhesive layer of a first strip-shaped film 210A, which is comprisedof the polarizing plate having a release film 211A bonded thereto withinterposition of the adhesive layer and is supplied from the front sideplate surface of a substrate 201 to be transported, when aforward-facing pre-severed end perpendicular to the longitudinaldirection of the film 210A has traveled a length corresponding to thelength of the substrate, with the first cutting means thus cutting thefilm 210A in a direction perpendicular to the longitudinal direction ofthe film so as to leave the release film 211A uncut. The second cuttingmeans 231B severs at least a polarizing plate and an adhesive layer of asecond strip-shaped film 210B, which is comprised of the polarizingplate having a release film 211B bonded thereto with interposition ofthe adhesive layer and is supplied from the reverse plate surface sideof the substrate 201 to be transported, when a forward-facingpre-severed end face perpendicular to the longitudinal direction of thefilm 210B has traveled a length corresponding to the length of thesubstrate, with the second cutting means thus cutting in a directionperpendicular to the longitudinal direction so as to leave the releasefilm 211B uncut, with the direction of an axis of light transmission ofthe polarizing plate of the second strip-shaped film being at rightangles to the direction of light transmission of the polarizing plate ofthe first strip-shaped film 210A when in the release film 211B iscombined with the release film 211A of the first strip-shaped film 210A.The first release film separating means 232A separates the release film211A from a first film piece 219A severed from the first strip-shapedfilm 210A by the first cutting means 231A. The second release filmseparating means 232B separates the release film 211B from a second filmpiece 219B severed from the second strip-shaped film 210B by the secondcutting means 231B. The bonding means 233 bonds the tacky surface of thefirst film piece 219A, separated from the release film 211A, to thecorresponding front side plate surface of the substrate 201 so that thesevered end face of the first film piece 219A is parallel to the frontside end face in the transporting direction of the substrate 201, whilealso bonding the tacky surface of the second film piece 219B, separatedfrom the release film 211B, to the corresponding reverse side platesurface of the substrate 201 so that the severed end face of the secondfilm piece 219B is parallel to the front side end face in thetransporting direction of the substrate 201. In this manner, thepolarizing plate may be bonded to each substrate surface simultaneously,continuously and automatically, while the yield of the polarizing platemay be raised to 100%. Moreover, by using two reel-out rolls of the samekind, the two polarizing plates may be bonded to the substrate surfacesto intersect the directions of the axes of light transmission of thepolarizing plates bonded with each other.

Referring to FIG. 16(B), the strip-shaped film (210A, 210B of FIG. 15),as applied in the present invention (second solution), is composed of apolarizing plate 216 and a release film 211 bonded to the polarizingplate with interposition of adhesive layers 214, 212 (phase differencefilm 213). In cases where it is used for an LCD for TN liquid crystal,the polarizing plate 216 has the direction of the axis of lighttransmission oriented obliquely with respect to the longitudinaldirection of the film. The angle of inclination between the longitudinaldirection of the film and the direction of the axis of the lighttransmission is preferably between 20° C. and 70° C. both inclusive andmore preferably between 40° C. and 50° C. both inclusive and isordinarily 45° (see FIG. 16(A)). As for the method for the preparationof this polarizing plate, JP Patent Kokai JP-A-2002-86554 should bereferred. Preferably, protective films 215, 217 are bonded to both sidesof the polarizing plate 216. The polarizing plate 216 used here has beenstretched obliquely relative to the longitudinal direction of the filmand hence termed an “obliquely stretched polarizing plate”. With use ofthe obliquely stretched polarizing plate, it is possible to supply thefilm continuously. The first strip-shaped film 210A and the secondstrip-shaped film 210B may be used in such a combination that, when thefirst strip-shaped film 210A and the second strip-shaped film 210B arecombined to each other with the release film 211A of the firststrip-shaped film 210A and the release film 211B of the secondstrip-shaped film 210B abutting against each other, the direction of theaxis of light transmission of the polarizing plate of the firststrip-shaped film 210A is perpendicular to the direction of the axis oflight transmission of the polarizing plate of the second strip-shapedfilm 210B. For example, in cases where the first strip-shaped film 210Ais used in which the direction of the axis of light transmission of thepolarizing plate is oriented 70° relative to the longitudinal direction,the second strip-shaped film 210B may be used in which the direction ofthe axis of light transmission of the polarizing plate is oriented 20°relative to the longitudinal direction. Preferably, the firststrip-shaped film 210A and the second strip-shaped film 210B (first filmpiece 219A and the second film piece 219B) are used in which thedirections of the oblique stretching (direction of the axis oftransmission) when seen from the respective tacky surfaces are the sameand equal to 45° (see FIG. 17). The reason is that, with use of thestrip-shaped films or film pieces having the same direction of the axisof light transmission, it is possible that the directions of the axes oflight transmission intersect each other when the polarizing plates arebonded to both surfaces of the substrate 201. Meanwhile, in cases wherethe polarizing plate 216 is used as LCD for a VA liquid crystal or asLCD for a liquid crystal of the IPS system, such a polarizing plate 216may be used in which the direction of the axis of light transmissionthereof is oriented parallel or perpendicular to the longitudinaldirection of the film. For example, in cases where the firststrip-shaped film 210A is used in which the direction of the axis oflight transmission of the polarizing plate is oriented parallel to thelongitudinal direction thereof, the second strip-shaped film 210B may beused the direction of the axis of light transmission of the polarizingplate is oriented at right angles to the longitudinal direction thereof.

In the case of a circular polarizing film composed of the obliquelystretched polarizing plate 216 (protective film 215) and a phasedifference film 213 bonded thereto with interposition of an adhesivelayer 214, such phase difference film 213 is preferably used which hasan axis of orientation perpendicular or parallel to the longitudinaldirection of the film. By so doing, the circular polarizing film can besupplied continuously. In the case of the circular polarizing film, ifthe axis of orientation of the phase difference film of the firststrip-shaped film (210A of FIG. 15) is parallel to the longitudinaldirection of the film, the axis of orientation of the phase differencefilm of the second strip-shaped film (210B of FIG. 15) is perpendicularto the longitudinal direction of the film.

There is no particular limitation to the thickness of the polarizingplate 216, which may, for example, be on the order of 5 through 100 μm.The width of the polarizing plate 216 may be suitably selected dependingon the size of the substrate to be bonded. The first strip-shaped film(210A of FIG. 15) and the second strip-shaped film (210B of FIG. 15) maybe of the same width. The adhesive layers 212, 214 may be of any commonadhesives used for bonding a substrate and an optical film together,such as acrylic-, polyurethane-, epoxy- or rubber-based adhesive. Therelease film 211 is of a release material commonly used for an opticalfilm, such as a polyethylene terephthalate film or a polyester film. Ainserting paper sheet 218 for protecting the film surface againstscratches etc. may be bonded to the surface of the polarizing plateopposite to the surface bonded to the release film 211. The strip-shapedfilms 210A, 210B may be supplied from the reel-out rolls 234A, 234B (seeFIG. 15)

The substrate 201 is a flat-plate-shaped member, such as a glasssubstrate or a plastic substrate used in a display equipment such as anLCD, or a plasma display equipment. It may also be a substrate havingcomponent parts, such as a liquid crystal cell or an electrode,previously mounted thereon. The substrate 201 is preferably of asubstantially quadrilateral shape, such as a square or a rectangle (seeFIG. 15 and FIG. 16(A)).

A first cutting means 231A and a second cutting means 231B are apush-cut cutter or a dicing cutter etc. used for cutting an optical filmhaving e.g., a cutter edge, a cylinder actuating the cutter edge and alower dead point position adjustment member for adjusting the lower deadpoint position of the cutter edge. By adjusting the lower dead pointposition to not more than 0.5 times as thick as the release film 211,the other layers of the strip-shaped film 210 excluding the release film211 (with a thickness of 10 through 50 μm), e.g., the polarizing plateor the adhesive layer, can be cut in a direction perpendicular to thelongitudinal direction of the film (referred to below as half-cutting)(see FIG. 15).

A first release film separating means 232A and a second release filmseparating means 232B are means for separating the release films 211Aand 211B from film pieces 219A and 219B, respectively (see FIG. 15) andmay be exemplified by a roller or a wedge member.

The release films 211A and 211B, separated from the film pieces 219A and219B may be taken up on takeup rolls 235A and 235B, respectively, forrecovery (see FIG. 15).

A bonding means 233 is a means for bonding the tacky surfaces of twofilm pieces 219A, 219B, freed of the release films 211A, 211B,simultaneously to corresponding positions of the substrate 201 so thatthe end face toward the transport direction of the substrate,transported by transporting means 236, will be parallel to the severedend faces of the film pieces 219A, 219B (see FIG. 15). The bonding means233 may, for example, be nip rolls (rubber or metal rolls) which thrustagainst both sides of the substrate. As for rolls, the combination oftwo rubber rolls with a hardness of 60 through 80° or the combination ofone rubber roll with a hardness of 60 through 80° and a metal roll ispreferred. The nip pressure of the rolls in bonding is preferably alinear pressure of 1 kg/cm or less.

The transporting means 236 is preferably a roller conveyor or a wheelconveyor horizontally transporting the substrate 201 on an array ofrolls or wheels. More preferably, an outer roller tube or a wheel ismounted on a shaft rotating via a bearing. The outer roller tube or thewheel is preferably rotated with a surface speed coincident with thespeed of the substrate being transported to prevent slip of the outerroller tube or the wheel which will damage the substrate.

An embodiment 2 (second solution) is now explained with reference to thedrawings. FIG. 18 is a side view schematically illustrating thestructure of a polarizing plate bonding apparatus. FIG. 19 is adeveloped perspective view schematically illustrating the relationshipbetween a substrate and stretching directions of polarizing platesbonded to both substrate surfaces by the polarizing plate bondingapparatus according to embodiment 1 of the present invention (secondsolution).

Referring to FIG. 18, a polarizing plate bonding apparatus 240 accordingto embodiment 2 of the second solution includes a first release filmseparating means 241A, a second release film separating means 241B, abonding means 242 and a cutting means 243. The first release filmseparating means 241A separates a release film 211A from a firststrip-shaped film 210A, which is composed of a polarizing plate and therelease film 211A bonded thereto with interposition of an adhesivelayer, and which is supplied from the front side plate surface of asubstrate 201 to be transported. The second release film separatingmeans 241B separates a release film 211B from a second strip-shaped film210B, which is composed of a polarizing plate and the release film 211Bbonded thereto with interposition of an adhesive layer and which issupplied from the reverse plate surface side of the substrate 201 to betransported. The direction of an axis of light transmission of thepolarizing plate of the second strip-shaped film is at right angles tothe direction of an axis of light transmission of the polarizing plateof the first strip-shaped film 210A when the release film 211B iscombined to the release film 211A of the first strip-shaped film 210A.The bonding means 242 bonds the tacky surface of the first strip-shapedfilm 210A, separated from the release film 211A, to the correspondingfront side plate surface of the substrate 201 so that the forwarddirection of the first strip-shaped film 211A coincides with thetransporting direction of the substrate 201, while also bonding thetacky surface of the second strip-shaped film 210B, separated from therelease film 211B, to the corresponding reverse side plate surface ofthe substrate 201 so that the proceeding direction of the secondstrip-shaped film 210B coincides with the transporting direction of thesubstrate 201. The cutting means 243 severs the first strip-shaped film210A and the second strip-shaped film 210B, bonded by the bonding means242 to both surfaces of the substrate 201, in a direction parallel tothe forward side end face or the rear end face in the transportingdirection of the substrate 201. In this manner, the polarizing plate maybe bonded to each substrate surface simultaneously, continuously andautomatically without stopping transportation of a substrate, while theyield of the polarizing plate may be raised to 100%. Moreover, employingtwo reel-out rolls of the same sort may bond the two polarizing platesto intersect the directions of the axes of light transmission of thepolarizing plates bonded to the respective substrate surfaces with eachother.

The release film separating means 241A, 241B, bonding means 242,reel-out rolls 244A, 244B, takeup rolls 245A, 245B and transportingmeans 246 of the polarizing plate bonding apparatus 240 of embodiment 2of the second solution (see FIG. 18) are substantially the same as therelease film separating means 232A, 232B, bonding means 233, reel-outrolls 234A, 234B, takeup rolls 235A, 235B and transporting means 236,respectively, of the polarizing plate bonding apparatus of embodiment 1of the second solution (see FIG. 15) The substrate 201 and thestrip-shaped film 210A, 210B used in the polarizing plate bondingapparatus 240 of embodiment 2 of the second solution are similar tothose used in embodiment 1 of the second solution. The location of thecutting means 243 of the polarizing plate bonding apparatus 240 ofembodiment 2 of the second solution differs from that of the cuttingmeans of the polarizing plate bonding apparatus of embodiment 1 of thesecond solution. Meanwhile, the bonding means 242 of FIG. 18 differs inthe fact that not the film piece but the unsevered strip-shaped films210A, 210B are bonded to both sides of the substrate 201.

The transporting means 246 of FIG. 18 includes the cutting means 243 ona transport line in the downstream from the bonding means 242. On thetransporting means 246, upstream from the bonding means 242, the endface toward the transport direction of the substrate 201 is desirablyabutted and transported at least before the bonding occurs, because thisimproves the yield of the polarizing plate.

The cutting means 243 of FIG. 18 cuts the first strip-shaped film 210Aand the second strip-shaped film 210B, bonded by the bonding means 242to both surfaces of the substrate 201, in a direction parallel to theforward side end face or the rear end face along the transport directionof the substrate 201. Since the release films 211A and 211B are notbonded at this time to the first strip-shaped film 210A and the secondstrip-shaped film 210B, respectively, the first strip-shaped film 210Aand the second strip-shaped film 210B are not half-cut, but are severedin their entirety substantially simultaneously.

The first strip-shaped film 210A and the second strip-shaped film 210Bare preferably used which have the same oblique stretching direction(direction of the axis of light transmission) viewed from the respectivetacky surfaces (see FIG. 19). The reason is that employing thestrip-shaped films of the same oblique stretching direction canintersect, the directions of the axes of light transmission when thepolarizing plate is bonded to each surface of the substrate 201.

Embodiment 3 of the present invention (second solution) is now explainedwith reference to the drawings. FIG. 20 schematically shows thestructure of a polarizing plate bonding apparatus according toembodiment 3 of the present invention (second solution). FIG. 21 is aplan view schematically showing the structure of a polarizing platebonding apparatus according to embodiment 3 of the present invention(second solution). FIG. 22 is a side view schematically showing thestructure of a first transport unit of the polarizing plate bondingapparatus according to embodiment 3 of the present invention (secondsolution). FIG. 23 is a side view schematically showing the structure ofa second transport unit of the polarizing plate bonding apparatusaccording to embodiment 3 of the present invention (second solution).

Referring to FIG. 20, the polarizing plate bonding apparatus ofembodiment 3 of the second solution is roughly divided into a firsttransport unit, an inverting unit and a second transport unit. In thefirst transport unit, a substrate (201A of FIG. 21), supplied from asupply unit, is transported, a polarizing plate reeled out from thereel-out roll is half-cut at a preset length, a release film isseparated, and the polarizing plate thus cut is bonded to the lower sideof a substrate (201B of FIG. 21). In the inverting unit, the substratetransported from the first transport unit (a substrate on lower surfaceof which is bonded a polarizing plate; 201B of FIG. 21) is invertedupside down so that the end face of the inverted substrate toward theforward direction of the inverted substrate is perpendicular to theproceeding direction. The inverted substrate (a substrate on the uppersurface of which is bonded a polarizing plate; 201C of FIG. 21) is sentto the second transport unit. In the second transport unit, thesubstrate sent from the inverting unit (a substrate on the upper surfaceof which is bonded a polarizing plate; 201D of FIG. 21) is transportedin a direction perpendicular to the direction of transport of thesubstrate by the first transport unit. A polarizing plate reeled outfrom the reel-out roll is half-cut and freed of the release film. The socut polarizing plate is bonded to the lower surface of the substrate togive a substrate (a substrate on both surfaces of which the polarizingplates are bonded; 201E of FIG. 21).

Referring to FIG. 22 and to FIG. 23, the structure of the polarizingplate bonding apparatus according to embodiment 3 of the second solutionis now explained in detail. A polarizing plate bonding apparatus 250includes a first transport means 251A for transporting a substrate 201as one end surface thereof is perpendicular to the direction of travel,and a first cutting means 252A which, when a severed end face toward thedirection of travel perpendicular to the longitudinal direction of afirst strip-shaped film 210A, comprised of a release film 211A bonded toa polarizing plate with interposition of an adhesive layer, has traveleda length corresponding to the length of the substrate 201, cuts at leastthe polarizing plate and the adhesive layer in a direction perpendicularto the longitudinal direction so as to leave the release film 211Auncut. The polarizing plate bonding apparatus also includes a firstrelease film separating means 253A for separating the release film 211Afrom the first film piece 219A severed by the cutting by the firstcutting means 252A, and a first bonding means 254A for bonding the tackysurface of the first film piece 219A, freed of the release film 211A, toa corresponding plate surface piece of the substrate 201, so that thesevered surface of the first film piece 219A will be parallel to theforward end face toward the direction of travel of the substrate 201transported by the first transport means 251A. The polarizing platebonding apparatus also includes an inverting means 255 for invertingupside-down, the substrate 201 which is transported by the firsttransport means 251A and the first film piece 219A is affixed to, sothat the end face toward the direction of travel of the invertedsubstrate 201 is perpendicular to the proceeding direction, and a secondtransporting means 251B for transporting the substrate 201, so fartransported by the first transport means 251A, in a directionperpendicular to the transporting direction of the first transport means251A. The polarizing plate bonding apparatus also includes a secondcutting means 252B for cutting at least a polarizing plate and anadhesive layer of the second strip-shaped film 210B in a directionperpendicular to the longitudinal direction thereof so as to leave arelease film 211B uncut, when a severed surface toward the direction oftravel perpendicular to the longitudinal direction of the secondstrip-shaped film 210B has traveled a length corresponding to thesubstrate 201 transported by the second transport means 251B. The secondstrip-shaped film 210B is supplied from the plate surface side of thesubstrate 201 opposite to the surface to which has been bonded the firstfilm piece 219A. The second strip-shaped film 210B includes thepolarizing plate and the release film 211B bonded thereto withinterposition of the adhesive layer. The direction of the axis of lighttransmission of the polarizing plate of the film 210B is perpendicularto the direction of the axis of light transmission of the polarizingplate of the first strip-shaped film 210A when the second strip-shapedfilm 210B is combined to the release film 211A of the first strip-shapedfilm 210A. The polarizing plate bonding apparatus also includes a secondrelease film separating means 253B for separating the release film 211Bfrom the second film piece 219B severed by the cutting with the secondcutting means 252B, and a second bonding means 254B for bonding thetacky surface of the second film piece 219B, freed of the release film211B, to the corresponding plate surface of the substrate 201 oppositeto the plate surface thereof bonded with the first film piece 219A, sothat the end face toward the direction of travel of the substrate 201transported by the second transport means 251B is parallel to thesevered surface of the second film piece 219B.

In the polarizing plate bonding apparatus 250 according to embodiment 3of the second solution, the film piece 219A is bonded from the undersideof the substrate 201, the substrate is inverted upside down and theinverted film piece 219A is bonded from the underside of the substrate201 in FIG. 20 to FIG. 23. Alternatively, the film piece 219A may bebonded from the upper side of the substrate 201, the substrate isinverted upside-down and the inverted film piece 219A is then bondedfrom the upper side of the substrate 201. Still alternatively, the filmpiece 219A may be bonded from the lower side of the substrate 201 andthe film piece 219A may be bonded from the upper side without invertingthe substrate 201. Still alternatively, film piece 219A may be bondedfrom the upper side of the substrate 201, and the film piece 219A may bebonded from the underside of the substrate 201 without inverting thesubstrate 201. With the polarizing plate bonding apparatus 250 of thetype in which the film piece 219A is bonded from the underside of thesubstrate 201, the substrate 201 is inverted upside down and the filmpiece 219A is bonded from the underside of the substrate 201, cutting(half-cut) is from the underside of the strip-shaped film, so thatcontaminants may be prohibited from intrusion

The substrate 201 and the strip-shaped films 210A, 210B, used in thepolarizing plate bonding apparatus 250 pertaining to embodiment 3 of thesecond solution, are the same as those used in embodiment 2 of thesecond solution. However, in cases where the longitudinal and transverselengths of the substrate 201 are of different magnitudes, the filmwidths of the first strip-shaped film 210A and the second strip-shapedfilm 210B may be of different magnitudes, in keeping with thecorresponding size of the substrate 201. In this case, the reel-outrolls, about which are wound the strip-shaped films, may be demarcatedfrom each other depending on the size (width) with advantage in the caseof roll exchanging operations. In the case of a circular polarizationfilm used, the axis of orientation of the phase difference film of thefirst strip-shaped film 210A is equated to the axis of orientation ofthe phase difference film of the second strip-shaped film 210B. In thismanner, the axes of orientation of the phase difference films in caseswhere film pieces are bonded to both substrate surfaces may be at rightangles to each other, while the strip-shaped films can be suppliedcontinuously.

The transport means 251A, 251B, cutting means 252A, 252B, release filmseparating means 253A, 253B, bonding means 254A, 254B, reel-out rolls256A, 256B and the takeup rolls 257A, 257B (see FIG. 22 and FIG. 23) inembodiment 3 of the second solution are substantially analogous with thetransport means 236, cutting means 231B, release film separating means232B, bonding means 233, reel-out roll 234B and the takeup roll 235B ofembodiment 1 of the second solution, respectively (see FIG. 15)

In the bonding means 254A of embodiment 3 of the second solution, thefilm piece 219A is bonded to only one side of the substrate 201. In thebonding means 254B, the film pieces 219A, 219B are apparently bonded toboth surfaces of the substrate 201. In actuality, however, the filmpiece 219B is bonded to only one side of the substrate 201.

The inverting means 255 is required when the directions of supplyingfilm pieces 219A, 219B in the first bonding means 254A, 254B are thesame, for example the film piece 219A is supplied from the underside ofthe substrate in the first bonding means 254A and the film piece 219B issupplied from the underside of the substrate in the second bonding means254B. Meanwhile, in cases where the directions of supplying the filmpieces 219A, 219B are opposite to each other in the bonding means 254A,254B, for example, the film piece 219A is bonded in the first bondingmeans 254A from the lower substrate surface and the film piece 219B isbonded in the second bonding means 254B from the upper side of thesubstrate, the inverting means 255 is not needed.

Embodiment 4 of the present invention (second solution) is now explainedwith reference to the drawings. FIG. 24 is a side view schematicallyshowing the structure of a first transport unit of a polarizing platebonding apparatus according to embodiment 4 of the present invention(second solution). FIG. 25 is a side view schematically showing thestructure of a second transport unit of the polarizing plate bondingapparatus according to embodiment 4 of the present invention (secondsolution).

Similarly to the polarizing plate bonding apparatus according toembodiment 3 of the second solution, shown in FIG. 20, the polarizingplate bonding apparatus of embodiment 4 of the second solution isroughly divided into a first transport unit, an inverting unit and asecond transport unit. In the first transport unit, a substrate (201A ofFIG. 21), supplied from a supply unit, is transported, a polarizingplate reeled out from a reel-out roll is separated from a release film,and the polarizing plate is bonded to the lower side of a substrate(201B of FIG. 21) and severed at a preset position. In the invertingunit, the substrate transported from the first transport unit (asubstrate on the lower one surface of which has been bonded thepolarizing plate; FIG. 21) is inverted upside-down so that the end facetoward the direction of travel of the as-inverted substrate isperpendicular to the direction of travel. The so inverted substrate (asubstrate on the upper one surface of which has been bonded thepolarizing plate; 201C of FIG. 21) is sent to the second transport unit.In the second transport unit, the substrate sent from the inverting unit(a substrate on the upper surface of which has been bonded thepolarizing plate; 201D of FIG. 21) is transported in a directionperpendicular to the direction of transport of the substrate by thefirst transport unit. The polarizing plate reeled out from the reel-outroll is freed of the release film. The polarizing plate is bonded to thelower surface of the substrate (a substrate on both surfaces of whichthe polarizing plates have been bonded; 201E of FIG. 21) and severed ata preset position.

Referring to FIG. 24 and to FIG. 25, the structure of the polarizingplate bonding apparatus according to embodiment 4 of the second solutionis now explained in detail. A polarizing plate bonding apparatus 260includes a first transport means 261A for transporting a substrate 201as one end surface of the substrate 201 is perpendicular to thedirection of travel, a first release film separating means 262A forseparating a release film 211A from a first strip-shaped film 210A,composed of a polarizing plate and the release film 211A bonded theretowith interposition of an adhesive layer, and a first bonding means 263Afor bonding the tacky surface of the first strip-shaped film 210A, freedof the release film 211A, to the corresponding plate surface piece ofthe substrate 201, so that the direction of travel of the first filmpiece 210A, coincides with the transport direction of the substrate 201transported by the first transport means 261A. The polarizing platebonding apparatus 260 also includes a first cutting means 264A forcutting the first strip-shaped film 210A, bonded by the first bondingmeans 263A to the substrate 201, in a direction parallel to the forwardor rear end face toward or opposite the transport direction of thesubstrate 201, transported by the first transport means 261A, and aninverting means 265 for inverting upside-down, the substrate 201 whichis transported by the first transport means 261A and the firststrip-shaped film 219A is affixed to, so that the end face toward thedirection of travel of the as-inverted substrate 201 will beperpendicular to the direction of travel, and a second transportingmeans 261B for transporting the substrate 201, transported by the firsttransport means 261A, in a direction perpendicular to the transportingdirection of the first transport means 261A. The polarizing platebonding apparatus also includes a second release film separating means262B for separating a release film 211B from a second strip-shaped film210B supplied from the plate surface side of the substrate 201 oppositeto the surface thereof bonded to the first film piece 219A. Thesubstrate 201 is transported by the second transporting means 261B. Thesecond strip-shaped film 210B is composed of a polarizing plate and therelease film 211B bonded to the polarizing plate with interposition ofan adhesive layer. An axis of light transmission of the polarizing plateof the second strip-shaped film 210B is perpendicular to an axis oflight transmission of the polarizing plate of the first strip-shapedfilm 210A when the release film 211B is combined to the release film211A of the first strip-shaped film 210A. The polarizing plate bondingapparatus also includes a second bonding means 263B for bonding a tackysurface of the second strip-shaped film 210B, freed of the release film211B, to a plate surface opposite to the surface of the substrate 201bonded to the film piece 219A of the first strip-shaped film 210A, sothat the direction of travel of the second strip-shaped film 210B willcorrespond to the transport direction of the substrate 201 transportedby the second transport means 261B, and a second cutting means 264B forcutting the second strip-shaped film 210B, bonded by the second bondingmeans 263B to the substrate 201, in a direction parallel to the forwardor rear end face toward or opposite the transport direction of thesubstrate 201 transported by the second transport means 261B.

In the polarizing plate bonding apparatus 260 according to embodiment 4of the second solution, the film piece 219A is bonded from the undersideof the substrate 201, the substrate is inverted upside down and the filmpiece 219A is bonded from the underside of the substrate 201 in FIG. 24and FIG. 25. Alternatively, the film piece 219A may be bonded from theupper side of the substrate 201, the substrate is inverted upside-downand the film piece 219A is then bonded from the upper side of thesubstrate 201, or the film piece 219A may be bonded from the undersideof the substrate 201, while the film piece 219A is bonded from the upperside of the substrate 201 without inverting the substrate 201. Stillalternatively, the film piece 219A may be bonded from the upper side ofthe substrate 201, while the film piece 219A is bonded from theunderside of the substrate 201 without inverting the substrate 201. Withthe polarizing plate bonding apparatus 250 of the type in which the filmpiece 219A is bonded from the underside of the substrate 201, thesubstrate is inverted upside-down and the film piece 219A is bonded fromthe underside of the substrate 201, half-cut is conducted from theunderside of the strip-shaped film, so that intrusion of contaminantsmay be prohibited meritoriously.

The substrate 201 and the strip-shaped films 210A, 210B, used in thepolarizing plate bonding apparatus 250, pertaining to embodiment 4 ofthe second solution, are similar to those used in embodiment 3 of thesecond solution.

The release film separating means 262A, 262B, bonding means 263A, 263B,reel-out rolls 266A, 266B and takeup rolls 267A, 267B in the embodiment4 of the second solution (see FIG. 24 and FIG. 25) are substantiallysimilar to the release film separating means 253A, 253B, bonding means254A, 254B, reel-out rolls 256A, 256B and takeup rolls 257A, 257B,respectively, of the polarizing plate bonding apparatus in embodiment 3of the second solution, respectively (see FIG. 22 and FIG. 23). Thetransport means 261A, 261B pertaining to embodiment 4 of the secondsolution (see FIG. 24 and FIG. 25) is similar to the transport means 246in embodiment 2 of the second solution (see FIG. 18). In a mannerdifferent from the cutting means in embodiment 3 of the second solution,the cutting means 264A, 264B in embodiment 4 of the second solution areprovided on a line in the downstream from the bonding means 263A, 263Bof the transport means 261A, 261B, and sever the strip-shaped films210A, 210B only on one side (underside) of the substrate. Meanwhile, thepoint of difference of the bonding means 254 is that not the film piecebut the non-cut strip-shaped films 210A, 210B are bonded to bothsurfaces of the substrate 201.

Embodiment of the Third Solution

Referring to the drawings, embodiment 1 of the present invention (thirdsolution) is now explained. FIG. 26 is a side view and a plan viewschematically showing the structure of a polarizing plate bondingapparatus according to embodiment 1 of the present invention (thirdsolution). FIG. 27 is a plan view and a cross-sectional view showing thestructure of a strip-shaped film of the polarizing plate bondingapparatus according to the embodiment 1 of the present invention (thirdsolution) FIG. 28 is a side view schematically showing the operation ofa cutting means of the polarizing plate bonding apparatus according toembodiment 1 of the present invention (third solution).

Referring to FIG. 26, a polarizing plate bonding apparatus 320 forbonding a polarizing plate (film piece 319) to a substrate 301 includesa release film separating means 321 for separating a release film 311from a strip-shaped film 310, which is composed of a polarizing plateand the release film 311 bonded to the polarizing plate withinterposition of an adhesive layer and which is supplied from onesurface of the substrate 301 to be transported, a bonding means 322 forbonding the tacky surface of the strip-shaped film 310 freed of therelease film 311 to the corresponding plate surface of the substrate 301so that the direction of travel of the strip-shaped film 310 coincideswith the transport direction of the substrate 301, and a cutting means323 for severing the strip-shaped film 310, bonded by the bonding means322 to one surface of the substrate 301, in a direction parallel to aforward end face or a rear end face of the substrate toward or oppositethe transport direction thereof, whereby polarizing plate film piecesmay be bonded continuously and automatically such as to diminish theamount of waste materials.

The strip-shaped film 310, used in the present invention (thirdsolution), is composed of a polarizing plate and the release film 311bonded thereto with interposition of an adhesive layer, and may, forexample, be a circular polarizing film, composed of a polarizing plate316 and a phase difference film 313 bonded thereto, as shown in FIG.27(B). In cases where it is used for an LCD for a TN liquid crystal, thepolarizing plate 316 has an axis of light transmission inclined by anangle preferably not less than 20° and not more than 70°, morepreferably not less than 40° and not more than 50°, and usually 45°relative to the longitudinal direction of the film (see FIG. 27(A)). Asfor the method for the preparation of this polarizing plate, referenceis had to the JP patent Kokai JP-A-2002-86554. Preferably, protectivefilms 315, 317 are bonded to both surfaces of the polarizing plate 316.This polarizing plate 316 is such a one stretched obliquely with respectto the longitudinal direction of the film, and hence is termed an“obliquely stretched polarizing plate”. With use of the obliquelystretched polarizing plate 316, continuous film supply becomes feasible.In the case of a film for circular polarization, composed of theobliquely stretched polarizing plate 316 (a protective film 315) and aphase difference film 313 bonded thereto by an adhesive layer 314, thephase difference film 313 is preferably such a one as having an axis oforientation perpendicular or parallel to the longitudinal direction ofthe film. In this case, the film for circular polarization can besupplied continuously. The thickness of the polarizing plate 316 ise.g., on the order of 5 through 100 μm. The width of the polarizingplate 316 is suitably selected depending on the size of the substrate tobe bonded. It is sufficient that the adhesives 312, 314 are ordinaryadhesives used for bonding the substrate and the optical film to eachother, for example, acrylic adhesive, polyurethane adhesive, epoxyadhesive or rubber-based adhesive. The release film 311 is a releasematerial and specifically an ordinary release material used for anoptical film, such as a polyethylene terephthalate film or a polyesterfilm. A inserting paper sheet 318 for preventing the film surface fromgrazing may be bonded to the surface of the polarizing plate 316opposite to the surface bonded to the release film 311. The strip-shapedfilm 310 is preferably supplied from a real out roll 324. (see FIG. 26).Meanwhile, in cases where the polarizing plate 316 is used for an LCDfor VA liquid crystal or a liquid crystal for an IPS system, thepolarizing plate 316 may be used, the direction of an axis of lighttransmission of which is oriented parallel or at right angles to thelongitudinal direction of the film, may be used.

The substrate 301 is a flat plate-shaped member, such as a glasssubstrate or a plastic substrate, used for a display apparatus, such asa liquid crystal device or a plasma display apparatus, and may be asubstrate, on which component parts, such as liquid crystal cell orelectrode, are mounted from the outset. The substrate 301 is preferablyof a substantially quadrilateral shape, such as a square or a rectangle(FIG. 26 and FIG. 27(A)).

The release film separating means 321 is a means for separating therelease film 311 from the strip-shaped film 310, and may be exemplifiedby a roll or a wedge member. The release film 311, separated by therelease film separating means 321 from the strip-shaped film 310, may betaken up on a takeup roll 325 for recovery (FIG. 26).

The bonding means 322 is a means for bonding the tacky surface of thestrip-shaped film 310, freed of the release film 311, to a correspondingposition on the substrate 301, so that the direction of travel of thestrip-shaped film 310 coincides with the transport direction of thesubstrate 301 (see FIG. 26). The bonding means may, for example, be anip roll thrusting each substrate surface from outside.

The cutting means 323 may be enumerated by a push-cut cutter or a dicingcutter used for cutting an optical film, and is composed of e.g., acutter edge, a cylinder actuating the cutter edge and a lower dead pointposition adjustment member for adjusting the lower dead point positionof the cutter blade (see FIG. 26). By adjusting the lower dead pointposition to not more than 0.5 times as thick as the release film 311, itis possible to cut only the strip-shaped film 310 in a directionperpendicular to the longitudinal direction of the film (see FIG. 26).In FIG. 26, the strip-shaped film 310 is severed once from above at anabutting portion between of the substrate 301 and a neighboringsubstrate 301. In cases where the film piece 319 is bonded at a presetspacing from the end(s) of the substrate 301 (so called bonding with amargin), cutting may be made twice in the vicinity of the abuttingportion, that is, a first cutting and a second cutting may be made onone substrate 301 and on the neighboring substrate 301, respectively. Inthe case of the bonding with a margin, unneeded chips (strip-likepieces) are produced. In cases where the strip-shaped film 310 is bondedcontinuously to the substrate without halting the substrate transport,it is sufficient that the cutting means 323 is operated in a certaindomain in association with the velocity and direction of transport ofthe substrate on the transport means (see FIG. 28). The movement of thecutting means 323 in this case may be enumerated by the movement of D1to D4 of FIG. 28 seen from the lateral side. At least the movement speedof D1 and the transport speed of the substrates 301A, 301B are equal toeach other, the cutting means 323 is lowered towards the substrateduring movement of D1 and the strip-shaped film 310 is severed fromabove at the abutting area between the substrates 301A and 301B. Themovement of the cutting means 323 may be a rotational movement seen fromthe lateral side.

The transport means 326 is a means for transporting the substrate 301towards the bonding means 322 or its extension while placing one endface of the substrate 301 at right angles to the proceeding direction,and is preferably a roller conveyor or a wheel conveyor which transportsthe substrate 301 horizontally on an array of rolls or wheels. Morepreferably, the outer roller cylinder or wheel is mounted on a shaftrotated via a bearing so that the outer roller cylinder or wheel isrotated at a surface velocity coincident with the velocity of thesubstrate being transported to prevent the substrate from being damagedby the relative slip between the outer roller cylinder or wheel and thesubstrate. The transport means 326 is preferably so arranged that pluralsubstrates 301 of a substantially quadrilateral shape and a fixed sizeare transported arrayed in series to the direction of travel and that,when the strip-shaped film 310 is bonded by the bonding means 322 to thesubstrate 301, in the course of the transport, the forward and rear endfaces toward and opposite, respectively, the transport direction of thesubstrate 301 are abutted against the forward or rear end faces of theneighboring substrates 301.

Referring to the drawings, embodiment 2 of the present invention (thirdsolution) is now explained. FIG. 29 is a side view and a plan viewschematically showing the structure of a polarizing plate bondingapparatus according to embodiment 2 of the present invention (thirdsolution). FIG. 30 is a side view showing the operation of cutting meansof the polarizing plate bonding apparatus according to embodiment 2 ofthe present invention (third solution).

A polarizing plate bonding apparatus 330 according to embodiment 2 ofthe third solution is substantially similar in structure to thepolarizing plate bonding apparatus according to embodiment 1 of thethird solution.

It is noted that cutting means 333A, 333B are means for cutting thestrip-shaped film 310, bonded to one surface of the substrate 301 by abonding means 332, in a direction parallel to the forward or rear endface toward or opposite the transport direction of the substrate 301. Inthe case of bonding with a margin, by which the film piece 319 is bondedto the substrate 301 with a certain margin from the end of the substrate301, the cutting means preferably includes two blades 333A, 333B forsimultaneously cutting into the surface of the strip-shaped film 310,bonded to the substrate 301, from the vertical direction, and forsevering in a direction perpendicular to the transport direction of thesubstrate 301, with the two blades 333A, 333B being spaced apart at apresent distance from each other (FIG. 30). The two blades 333A, 333Bsever the strip-shaped film 310 on the plate surfaces of the respectiveseparate substrates 301A, 301B (see FIG. 30). It is preferred in thiscase to provide a suction means 337 between the blades 333A. 333B forsucking unneeded cutting chips (strips) 302 of the severed strip-shapedfilm 310. The suction means 337 operates along with the two blades 333A,333B. Even in this case, the two blades 333A, 333B may be operated inkeeping with the velocity and the direction of transport of thesubstrate 301 on transport means 336 in a certain domain. In suchcutting, the forward and rear end faces of the substrate 301B along thetransport direction thereof are preferably abutted against the forwardor rear end faces of the neighboring substrate 301B along the transportdirection thereof, as shown in FIG. 30. The reason is that, by bondingthe strip-shaped film 310 as the two substrates 301 abut against eachother, the cut chips 302 may be decreased in size to raise the yield ofthe polarizing plates.

Embodiment 3 of the present invention (third solution) is explained withreference to the drawings. FIG. 31 is a side view schematically showingthe structure of a polarizing plate bonding apparatus according toembodiment 3 of the present invention (third solution).

A polarizing plate bonding apparatus 340 according to embodiment 3 ofthe third solution is substantially similar in structure to thepolarizing plate bonding apparatus according to embodiment 1 of thethird solution except the mounting positions of a release filmseparating means 341, reel-out roll 344 and takeup roll 345. Thispolarizing plate bonding apparatus 340 includes, below the substrate 301transported on transporting means 346, the release film separating means341, reel-out roll 344 and takeup roll 345. By supplying thestrip-shaped film 310 from the lower side of the plate surface of thesubstrate 301 to be transported, and by having the strip-shaped film 310bonded in position, it is possible to prevent intrusion of contaminantsas well as to assure easy exchange of rolls of the strip-shaped films.

Embodiments of the Fourth Solution

Referring to the drawings, Embodiment 1 of the present invention (fourthsolution) is now explained. FIG. 32 is a side view schematically showingthe structure of a polarizing plate bonding apparatus according toembodiment 1 of the present invention (fourth solution). FIG. 33 is aplan view and a cross-sectional view showing the structure of astrip-shaped film used in the polarizing plate bonding apparatusaccording to embodiment 1 of the present invention (fourth solution).FIG. 34 is a perspective view schematically showing the operation ofbonding and the state of selvedge separation by the polarizing platebonding apparatus according to embodiment 1 of the present invention(fourth solution).

Referring to FIG. 32, a polarizing plate bonding apparatus 420 forbonding a polarizing plate (film piece 419) to a substrate 401 includesa release film separating means 421, a bonding means 422 and a selvedgeseparating means 423, for automatically bonding the film piece of apolarizing plate without halting the apparatus. The release filmseparating means 421 separates a release film 411 from a strip-shapedfilm 410 which is composed of a polarizing plate and the release film411 bonded thereto with interposition of an adhesive layer and issupplied from one plate surface of the substrate 410, wherein at leastthe polarizing plate and the adhesive layer of the strip-shaped film 410are cut while keeping the release film 411 uncut in such a manner that aplurality of rectangular profiles are made in advance each of whichcorresponds to the substrate 401 in the film surface, at least one ofthe sides of each rectangular profiles being perpendicular to thelongitudinal direction of the film. The bonding means 422 bonds at leastthe tacky surface of the rectangular inner portion (film piece 419) ofthe strip-shaped film 410 freed of the release layer 411 to thecorresponding plate surface of the substrate 401 so that the directionof travel the strip-shaped film 410 coincides with the transportdirection of the substrate 401. The selvedge separating means 423separates a selvedge 402 of the strip-shaped film 410 other than therectangular inner portion (film piece 419) from the substrate 401.

The strip-shaped film 410 used in the present invention (fourthsolution) is composed of a polarizing plate and the release film 411bonded thereto with interposition of an adhesive layer, and may, forexample, be a film of circular polarization composed of a polarizingplate 416 and a phase difference film 413 bonded together, as shown inFIG. 33(B). In cases where it is used for an LCD for TN liquid crystal,the polarizing plate 416 has the direction of an axis of lighttransmission oriented obliquely with respect to the longitudinaldirection of the film. The angle of inclination between the longitudinaldirection of the film and the axis of the light transmission ispreferably between 20° C. and 70° C. both inclusive, more preferablybetween 40° C. and 50° C. both inclusive, and is ordinarily 45° (seeFIG. 33(A)). As for the method for the preparation of this polarizingplate, reference is had to JP Patent Kokai JP-A-2002-86554. Preferably,protective films 415, 417 are bonded to both sides of the polarizingplate 416. The polarizing plate 416 used here has been stretched in anoblique direction relative to the longitudinal direction of the film andhence termed an “obliquely stretched polarizing plate”. With use of theobliquely stretched polarizing plate 416, it is possible to supply thefilm continuously. In the case of a film for circular polarization,composed of the obliquely stretched polarizing plate 416 and the phasedifference film 413 bonded together with interposition of an adhesivelayer 414, the phase difference film 413 having an axis of orientationperpendicular or parallel to the longitudinal direction of the film isdesirably used. By so doing, the film for circular polarization can besupplied continuously. The thickness of the polarizing plate 416 ise.g., 5 through 100 μm. The width of the polarizing plate 416 issuitably selected depending on the size of the substrate bonded. In viewof ease with which the selvedge 402 may be peeled off from the substrate401 continuously, the width of the polarizing plate 416 is preferablylarger than the width of the substrate 401. The adhesive layers 412, 414may be of any common adhesives used for bonding a substrate and anoptical film together, such as acrylic-, polyurethane-, epoxy- orrubber-based adhesive. The release film 411 is of a release materialcommonly used for an optical film, such as a polyethylene terephthalatefilm or a polyester film. A inserting paper sheet 418 for protecting thefilm surface against scratches may be bonded to the surface of thepolarizing plate 416 opposite to the surface bonded to the release film411. The strip-shaped film 410 is preferably supplied from the reel-outrolls 424 (see FIG. 32). Meanwhile, in cases where the polarizing plateis used as LCD for a VA liquid crystal or as LCD for a liquid crystal ofthe IPS system, such a polarizing plate 416 may be used, in which thedirection of an axis of light transmission of the polarizing plate isoriented parallel or perpendicular to the longitudinal direction of thefilm.

The strip-shaped film 410 used in the embodiment 1 of the fourthsolution has a plurality of rectangular profiles which correspond to theshape of the substrate 401 within the film surface, at least one side ofthe rectangle being perpendicular to the longitudinal direction of thefilm, by cutting at least the polarizing plate and the adhesive layer,with keeping the release film 411 uncut. The inner area of the producedrectangle becomes a film piece 419 actually bonded to the substrate 401.The outer area outside the rectangle becomes a selvedge 402 not used forbonding the strip-shaped film to the substrate 401. The selvedge 402 isadapted to be continuously taken up by a selvedge takeup roll 426. Tothis end, both lateral sides of the strip-shaped film 410 are left in anuncut continuous state, while the width-wise portions defined betweenadjacent film pieces 419 connect to the lateral sides of the stripshaped film 410, such that, the selvedge 402,: without the film piece419, presents a ladder shape (FIG. 34)

The substrate 401 is a flat-plate-shaped member, such as a glasssubstrate or a plastic substrate, used for a display device, such as aliquid crystal display device or a plasma display device. It may also bea substrate having component parts, such as a liquid crystal cell or anelectrode, pre-mounted thereon. The substrate 401 is preferably of asubstantially quadrilateral shape, such as a square or a rectangle (seeFIG. 32 and FIG. 33(A)).

The release film separating means 421 is a means for separating therelease film 411 from the strip-shaped film 410 (film piece 419 andselvedge 402) and may be exemplified by a roll or a wedge member. Therelease film 411 separated from the strip-shaped film 410 (film piece419 and selvedge 402) by the release film separating means 421 may betaken up on a release film takeup roll 425 and recovered (see FIG. 32).

The bonding means 422 is a means for bonding a tacky surface of the filmpiece 419 of the strip-shaped film 410, freed of the release film 411,to a corresponding position of the substrate 401 so that the severed endface toward the direction of travel the strip-shaped film 410 isparallel to the end face toward the direction of travel the substrate(see FIG. 32) and may, for example, be a nip roll thrusting bothsubstrate sides from outside.

The selvedge separating means 423 is a means for peeling the selvedge402 of the strip-shaped film 410 except the film piece 419 from thesubstrate 401 and may, for example, be a roll (FIG. 32 and FIG. 34). Theselvedge separating means 423 of embodiment 1 of the fourth solution hasa roll(s) in common with the bonding means 422 and folds the selvedge402 in a direction away from the substrate 401, with the roll as a pointof fulcrum, to peel off only the selvedge 402. The selvedge 402, peeledfrom the selvedge separating means 423, is taken up by a selvedge takeuproll 426.

A transporting means 427 is a means for transporting the substrate 401in a direction towards the bonding means 422 or its extension, with anend face of the substrate 401 at right angles to the direction oftravel, and is preferably a roller conveyor or a wheel conveyor forhorizontally transporting the substrate 401 on an array of rollers orwheels. More preferably, the outer roller cylinder or wheel is mountedon a shaft rotated via a bearing so that the outer roller cylinder orwheel is rotated at a surface velocity coincident with the velocity ofthe substrate being transported to prevent the substrate from beingdamaged by the relative slip between the outer roller cylinder or wheeland the substrate. The transport means 427 is preferably so arrangedthat plural substrates 401 of a substantially quadrilateral shape and afixed size are transported arrayed in series to the direction of traveland that, when the strip-shaped film 410 (film piece 419) is bonded bythe bonding means 422 to the substrate 401, in the course of thetransport, the forward and rear end faces along the transport directionof the substrate 401 are abutted against the forward or rear end facesof the neighboring substrates 401.

Meanwhile, in cases where fine positioning adjustment between the tackysurface of the film piece 419 and the corresponding portion of thesubstrate 401 is required, it is possible to use positioning means foradjusting the positions of the two by detecting the positions of thefilm pieces 419 of the strip-shaped film 410 supplied and the positionof the substrate 401 transported, using position detection means, suchas image inspection device.

Embodiment 2 of the present invention (fourth solution) is now explainedwith reference to the drawings. FIG. 35 is a side view schematicallyshowing the structure of a polarizing plate according to the embodiment2 of the present invention (fourth solution).

Referring to FIG. 35, a polarizing plate bonding apparatus 430 accordingto Embodiment 2 of the fourth solution is similar in structure to thepolarizing plate bonding apparatus according to Embodiment 1 of thefourth solution, except a cutting means 438 and a reel-out roll 434, andthe operation as from the separation of the release film 411 untilpeel-off of the selvedge 402 is similar to the operation of Embodiment 1of the fourth solution.

With the reel-out roll 434, the strip-shaped film 410 is not cut into arectangular shape in advance. The structure of the reel-out roll 434(material, shape etc) except not being cut is similar to that of thereel-out roll used in embodiment 1 of the fourth solution.

The cutting means 438 is a means for cutting at least the polarizingplate and the adhesive layer, so as to leave the release film 411 uncut,in the strip-shaped film 410, which is composed of the polarizing plateand the release film 411 bonded thereto with interposition of theadhesive layer, and which is supplied from one plate surface of thesubstrate 401 to be transported, so that at least one side of therectangular shape of the strip-shaped film 410 is perpendicular to thelongitudinal direction of the film, the rectangular profilecorresponding to the shape of the substrate 401 in the film region. Thecutting means 438, used for cutting an optical film, is provided overthe strip-shaped film 410 extending from a reel-out roll 434 up to therelease film separating means 431. The cutting means may be composed ofe.g., a cutter blade having a Thomson blade cutting to a rectangularshape, a cylinder driving a cutter blade and a lower dead pointadjustment member for adjusting the lower dead point position of thecutter blade. By adjusting the lower dead point position to not morethan 0.5 times as thick as the release film 411, solely the strip-shapedfilm 410 can be cut in a direction perpendicular to the longitudinaldirection of the film.

Referring to the drawings, Embodiment 3 of the present invention (fourthsolution) is now explained. FIG. 36 is a side view schematically showingthe structure of a polarizing plate bonding apparatus according toembodiment 3 of the present invention (fourth solution). FIG. 37 is aperspective view schematically showing the operation of bonding by thepolarizing plate bonding apparatus and the state of selvedge separationaccording to embodiment 3 of the present invention (fourth solution).

Referring to FIG. 36, a polarizing plate bonding apparatus 440 accordingto embodiment 3 of the fourth solution includes a release filmseparating means 441 for separating a release film 411 from thestrip-shaped film 410, composed of a polarizing plate, which has an axisof light transmission oriented obliquely relative to the longitudinaldirection of the film, and the release film 441 bonded thereto withinterposition of an adhesive layer, with the strip-shaped film 410 beingsupplied from one plate surface side of the transported substrate 401.The polarizing plate bonding apparatus also includes a bonding means 442for bonding at least the tacky surface of the strip-shaped film 410,freed of the release film 411, to a corresponding plate surface of thesubstrate 401, so that the direction of travel of the strip-shaped film410 coincides with the transport direction of the substrate 401. Thepolarizing plate bonding apparatus also includes a cutting means 448 forcutting the strip-shaped film 410 in an area in which the strip-shapedfilm 410 has been bonded to the substrate 401, so that at least one sideof a rectangular shape of the film in register with the substrate 401 isperpendicular to the longitudinal direction of the film, and a selvedgeseparating means 443 for separating the selvedge 402 of the strip-shapedfilm 410 except the inner area within the rectangular shape (film piece419) from the substrate 401.

In a polarizing plate bonding apparatus 440 of embodiment 3 of thefourth solution, the strip-shaped film 410 not cut to a rectangularshape in advance, is used. After bonding the strip-shaped film 410 tothe substrate 401, the strip-shaped film 410 is cut on the substrate 401to a necessary size. After cutting the strip-shaped film 410, only theunneeded selvedge 402 of the strip-shaped film 410 is peeled off.

The strip-shaped film 410 is not cut to a rectangular shape in advanceand, except this point, the configuration of the reel-out roll 444, suchas shape or component material thereof, is the same as that of thereel-out roll used in Embodiment 1 of the fourth solution.

The release film separating means 441 is similar to the release filmseparating means of embodiment 1 of the fourth solution. In distinctionfrom embodiment 1 of the fourth solution, the bonding means 442 isseparated from the selvedge separating means 443. The location ofbonding of the strip-shaped film 410 is spaced from the location ofpeeling off the selvedge 402 a distance equal to or longer than the filmpiece length. A cutting means 448, similar to the cutting means ofembodiment 2 of the fourth solution, is arranged between the location ofbonding the strip-shaped film 410 and the location of peeling off theselvedge 402. The cutting means 448 cuts only the strip-shaped film 410,bonded to the substrate 401, to a rectangular shape on the substrate(see FIG. 37). After this cutting, the selvedge separating means 443continuously peels off the unneeded selvedge 402 of the strip-shapedfilm, as the needed film piece 419 is left bonded to the substrate 401.

Referring to the drawings, embodiment 4 of the present invention (fourthsolution) is now explained. FIG. 38 is a side view schematically showingthe structure of a polarizing plate bonding apparatus according toembodiment 4 of the present invention (fourth solution).

A polarizing plate bonding apparatus 450 according to the embodiment 4of the fourth solution bonds a polarizing plate film to the lower side(underside) of the substrate 401, transported substantiallyhorizontally, from the lower side of the substrate 401, and includes arelease film separating means 451, a reel-out roll 454, a release filmtakeup roll 455 and a selvedge takeup roll 456, below the level of atransport means 457. The means of embodiment 4 of the fourth solutionare similar in operation to the corresponding means of the polarizingplate bonding apparatus according to embodiment 1 of the fourthsolution. The polarizing plate bonding apparatus 450 according toembodiment 4 of the fourth solution substantially corresponds to 180°inversion of the polarizing plate bonding apparatus 450 according toembodiment 1 of the fourth solution (see FIG. 32 and FIG. 38).Alternatively, the polarizing plate bonding apparatus 450 according toEmbodiment 4 of the fourth solution may be 180° inversion of thepolarizing plate bonding apparatus according to embodiment 2 or 3 of thefourth solution.

Embodiment 5 of the present (fourth solution) is now explained withreference to the drawings. FIG. 39 is a side view schematically showingthe structure of a polarizing plate bonding apparatus according toEmbodiment 5 of the present invention (fourth solution).

A polarizing plate bonding apparatus 460 according to Embodiment 5 ofthe fourth solution bonds a polarizing plate film to the substrate 401simultaneously from upper and lower surfaces thereof as the substrate401 is transported substantially horizontally. Specifically, releasefilm separating means 461A, 461B, reel-out rolls 464A, 464B, releasefilm takeup rolls 465A, 465B and selvedge takeup rolls 466A, 466B arearranged above and below the level of a transport means 467. The meansof Embodiment 4 of the fourth solution are similar in operation to thecorresponding means of Embodiment 1 of the fourth solution. The means ofEmbodiment 5 of the fourth solution are similar in operation to thecorresponding means of Embodiment 1 of the fourth solution. Thepolarizing plate bonding apparatus 460 according to Embodiment 5 of thefourth solution is analogous to the combination of the items of thepolarizing plate bonding apparatus of Embodiment 1 of the fourthsolution which except the transport means are inverted. However, thesame may be applied to the case of the polarizing plate bondingapparatus of Embodiment 2 or 3 of the fourth solution. It is noted thatthe first strip-shaped film 410A and the second strip-shaped film 410Bare used in such a combination in which, when the release film 411A ofthe first strip-shaped film 410A is combined to the release film 411B ofthe second strip-shaped film 410B, the direction of an axis of lighttransmission of the first strip-shaped film 410A is perpendicular to thedirection of an axis of light transmission of the second strip-shapedfilm 410B. For example, in cases where the first strip-shaped film 410Ais used in which the direction of the axis of light transmission of thepolarizing plate is oriented 70° relatve to the longitudinal direction,it is possible to use the second strip-shaped film 410B in which thedirection of the axis of light transmission of the polarizing plate isoriented 20° relatve to the longitudinal direction. In cases where it isused for the LCD for a VA liquid crystal or the LCD for an ISP liquidcrystal, the polarizing plate 416 may be used in which the direction ofthe axis of light transmission of the polarizing plate is orientedparallel or perpendicular relative to the longitudinal direction of thefilm. For example, in cases where the first strip-shaped film 410A isused in which the direction of the axis of light transmission of thepolarizing plate is oriented parallel to the longitudinal direction, itis possible to use the second strip-shaped film 410B in which thedirection of the axis of light transmission of the polarizing plate isoriented perpendicular to the longitudinal direction.

[Examples]

Referring to the drawings, an example of the present invention (firstsolution) is explained. FIG. 13 is a side view schematically showing thestructure of a polarizing plate bonding apparatus according to anexample of the present invention (first solution). This polarizing platebonding apparatus 170 includes a reel-out means 171, a first payout roll172, a second payout roll 173, a film transporting conveyor 174, acutting means 175, a film piece transporting conveyor 176, a separatingroll 177, a third payout roll 178, a fourth payout roll 179, a takeupmeans 180, a first substrate transporting conveyor 181, a first positionguide means 182, a receiving roll 183, a pressure bonding roll 184, asecond substrate transporting conveyor 185, a second position guidemeans 186, an encoder, a film piece position sensor, a substratepositioning member and a control means.

The substrate (120 of FIG. 13), used here, is a flat-plate-shapedrectangular liquid crystal display substrate for TN type liquid crystal.The reel-out roll (187 of FIG. 13) is a roll formed by taking up astrip-shaped film 110, obtained on layering a release film 111, anadhesive layer 112, a phase difference film 113, an adhesive layer 114,a protective film 115, an oblique stretched polarizing plate 116, aprotective film 117 and an inserting paper sheet 118, in this order frombelow upward, so that the inserting paper sheet 118 is on the frontsurface, as shown in FIG. 2(B). Referring to FIG. 2(A), the obliquestretched polarizing plate 116 is a polarizing plate having an axis oflight transmission approximately 45° relative to the longitudinaldirection of the film. The phase difference film 113 has an axis oforientation which is the same as the longitudinal direction of the film.The takeup roll (188 of FIG. 13) is a roll for taking up the releasefilm 111 separated from the strip-shaped film 110 (film piece 119).

The reel-out means 171 is a means for supporting the reel-out roll 187in a horizontal state and for reeling out the strip-shaped film 110 fromthe reel-out roll 187, and includes a shaft (not shown) for rotationallysupporting the reel-out roll 187, and a brake (not shown) for brakingthe rotation of this shaft (see FIG. 13). By this brake, excess reel-outof the reel-out roll 187 is prohibited. A band brake comprising a bandfor tightening the outer rim of the disc mounted on the shaft is used,also it is possible to use any other suitable brake.

The first payout roll 172 and the second payout roll 173 are rolls, notdriven, for paying out the reeled-out strip-shaped film 110 to the filmtransporting conveyor 174 at a required angle (see FIG. 13).

The film transporting conveyor 174 is a means for transporting thereeled out strip-shaped film 110 towards the cutting means 175, and isherein a suction conveyor (belt conveyor) for transporting the film 110at a preset angle while sucking it (see FIG. 13). The belt is stretchedin a direction perpendicular to the direction of travel to prevent thewidth-wise center thereof from sagging. The film transporting conveyor174 is driven in a controlled fashion depending on the positions of thefilm piece 119 and the substrate 120.

The cutting means 175 is a means for cutting (half-cutting) the portionof the strip-shaped film 110 other than the release film 111 in adirection perpendicular to the longitudinal direction, and includes acutter and a driving means for driving the cutter (see FIG. 13). Thecutting means 175 is also controlled to cut the strip-shaped film whenthe strip-shaped film travels a preset length (the size necessary forbonding the film to the substrate 120), depending on the positions ofthe film piece and the substrate. With half-cutting, the cutting isconducted from the lower side surface (the surface towards the insertingpaper sheet) of the strip-shaped film 110, so that cutting chips hardlyreach the release film 111 (the side of the tacky surface).

The film piece transporting conveyor 176 is a means for transporting thefilm piece 119, severed by the cutting means 175, towards the pressurebonding roll 184, and is a suction conveyor (belt conveyor) fortransporting the film piece 119 towards the pressure bonding roll as theinserting paper sheet surface of the film piece 119 is sucked on thebelt (see FIG. 13). The transport surface of the film piece transportingconveyor 176 is on the extension of the transport surface of the filmtransporting conveyor 174. The belt is tensioned in a directionperpendicular to the direction of travel and is thereby prohibited fromsagging at its transverse mid position. The film piece transportingconveyor 176 is also driving-controlled, depending on the positions ofthe film piece 119 and the substrate 120, and is synchronized with theoperation of the film transporting conveyor 174.

The separating roll 177 is arranged at about the mid portion on the beltfeed side of the film piece transporting conveyor 176 and has its rollaxis perpendicular to the direction of travel of the film piece. It is anon-driven roll for separating only the release film 111 from the filmpiece 119.

The third payout roll 178 and the fourth payout roll 179 are non-drivenrolls for paying out the release film 111, separated by the separatingroll 177, towards the take-up roll 188 (see FIG. 13).

The takeup means 180 is a means for rotationally driving a takeup roll188 to take up the release film 111. The takeup means 180 isdriving-controlled depending on the positions of the film piece 119 andthe substrate 120 (see FIG. 13)

The first substrate transporting conveyor 181 is a roller conveyor(wheel conveyor) composed of an array of rolls for transporting thesubstrate 120, to which the film piece 119 has not been bonded, in ahorizontal and predetermined direction as shown in FIG. 13 (FIG. 13A).The first substrate transporting conveyor 181 is driving-controlled,depending on the positions of the film piece 119 and the substrate 120.

The first position guide means 182 is a guide member regulating thesubstrate position from both sides (of the substrate 120) in a directionperpendicular to the direction of travel of the substrate 120 on thefirst substrate transporting conveyor 181 for guiding the direction oftravel (see FIG. 13). The first position guide means 182 thrusts thesubstrate 120 by the spring pressure of a guide member on one sidetowards a stationary guide member on the opposite side for guiding thesubstrate 120 in a predetermined direction.

The receiving roll 183 is a roll for transporting the substrate 120,transported by the first substrate transporting conveyor 181, towardsthe second substrate transporting conveyor 185, and for sustaining thethrusting pressure of the pressure bonding roll 184 from the lower side(see FIG. 13). The receiving roll 183 is also driving-controlled,depending on the positions of the film piece 119 and the substrate 120.

The pressure bonding roll 184 is a nip roll for thrusting the lowersurface of the substrate 120 towards the receiving roll 183 to entanglethe film piece 119 for pressure bonding the film piece to the lowerplate surface of the substrate 120 (see FIG. 13). The pressure bondingroll 184 is mounted to a lift mechanism, not shown. This lift mechanismis controlled, depending on the positions of the film piece 119 and thesubstrate 120, in such a manner that it is lifted up for applying thethrusting pressure to the receiving roll 183, for bonding the film piece119 to the substrate 120, and is lowered between the end of the bondingof one substrate 120 and the completion of preparation for bonding thenext substrate 120.

The second substrate transporting conveyor 185 is a roller conveyor(wheel conveyor) composed of an array of rolls for transporting thesubstrate 120, emerging through the spacing between the pressure bondingroll 184 and the receiving roll 183 in a state bonded to the film piece119, in a horizontal and predetermined direction (see FIG. 13). Thesecond substrate transporting conveyor 185 is also driving-controlled,depending on the positions of the film piece 119 and the substrate 120,and is synchronized with the operation of the first substratetransporting conveyor 181.

The second position guide means 186 is a guide member for regulating thesubstrate position, in a direction perpendicular to the direction oftravel on the second substrate transporting conveyor 185, from bothsides, for guiding the direction of travel of the substrate (see FIG.13) The substrate 120 is thrust by a spring pressure on one side guidemember against the opposite side stationary guide member for guiding thesubstrate 120 in a predetermined direction.

The encoder, not shown, is a device for measuring the supplied quantityof the strip-shaped film 110. In the present example, the number ofrotations of the pulley of the film piece transporting conveyor 176 ismeasured for measuring the supplied quantity of the strip-shaped film110.

The film piece position sensor, not shown, is a photosensor fordetecting the position of (the forward end of) the film piece 119, sentto the pressure bonding roll 184 of the film piece transporting conveyor176.

The substrate positioning member, not shown, is arranged in the vicinityof a bonding unit having the receiving roll 183 and the pressure bondingroll 184, and operates as a stopper for obstructing the movement of thesubstrate 120. After the bonding of one substrate 120 is completed andthe substrate is sent to the downstream side, the stopper emerges on thetransport line, and collides with the end face of the next substrate120, transported by the first substrate transporting conveyor 181. Atthe same time as the substrate transport is obstructed by the stopper, adetection device of the substrate positioning member indicates the factof the substrate arrival to stop the driving of the first substratetransporting conveyor 181. The film piece 119 is fed out from thestandby position, as measured by the encoder, until the front end of thefilm piece 119 reaches the bond position for the substrate 120. Afterthe pressure bonding roll 184 bonds the front end of the film piece 119to the substrate 120 between the roll 184 and the receiving roll 183,the stopper is receded and disengaged from the substrate. The rotationof the receiving roll 183, transport of the substrate 120 and the supplyof the film piece 119 are then carried out in a synchronized manner sothat the substrate 120 and the film piece 119 are bonded together by thereceiving roll 183 and the pressure bonding roll 184.

The control means, not shown, is a computer for controlling the drivingof the film transporting conveyor 174, cutting means 175, film piecetransporting conveyor 176, takeup means 180, first substratetransporting conveyor 181, receiving roll 183, pressure bonding roll184, substrate positioning member and the second substrate transportingconveyor 185, depending on signals from detecting devices of theencoder, the film piece position sensor, and substrate positioningmember.

The operation of the polarizing plate bonding apparatus according to anexample of the present invention (first solution) is now explained.

Referring to FIG. 13, the strip-shaped film 110, reeled out from thereel-out roll 187, is paid out by the first payout roll 172 and thesecond payout roll 173 at an angle consistent with the transport surfaceof the film transporting conveyor 174.

The so paid out strip-shaped film 110 is transported by the filmtransporting conveyor 174 towards the cutting means 175 and, when thesevered end face of the foremost part of the strip-shaped film 110 hastraveled a preset length (a length corresponding to the substrate lengthor a length slightly shorter than it), further travel of thestrip-shaped film 110 is halted and the strip-shaped film 110 ishalf-cut (cut other layers or portions of the film except the releasefilm) in a direction perpendicular to its longitudinal direction. Thishalf-cutting is performed every time the severed forward side end faceof the strip-shaped film 110, extending at right angles to thelongitudinal direction in the strip-shaped film 110, has traveled alength corresponding to the length of the substrate 120.

The film piece 119, cut out by the half-cutting, is transported by thefilm piece transporting conveyor 176 to the pressure bonding roll 184,so that only the release film 111 is separated from the film piece 119,which passes through the gap between the film piece transportingconveyor 176 and the separating roll 177, by the separating roll 177 onthe transport surface of the film piece transporting conveyor 176. Theso separated release film 111 is paid out by the third payout roll 178and the fourth payout roll 179 so as to be taken up on the takeup roll188.

The film piece 119, freed of the release film 111, is supplied to aspacing between the pressure bonding roll 184 and the lower surface ofthe substrate 120 traveling through the space between the receiving roll183 and the pressure bonding roll 184, to fit with the bonding positionof the substrate 120 transported by the first substrate transportingconveyor 181 (the position on the substrate at which the severed endface of the film piece 119 is parallel to the forward side end face ofthe substrate 120), with the tacky surface thereof directed to thesubstrate 120, and then is transported to the second substratetransporting conveyor 185, as the film piece is bonded to the substrateunder the pressure exerted by the pressure bonding roll 184. Thesubstrate 120, passed through the spacing between the receiving roll 183and the pressure bonding roll 184, has the film piece 119 bonded to itslower surface, and is transported in this state by the second substratetransporting conveyor 185.

[Meritorious Effect of the Invention]

(Meritorious Effect of the First Solution)

According to the present invention (first solution) the polarizing platecan be bonded automatically and continuously.

Moreover, according to the present invention (first solution), in whicha film piece is supplied from the lower side of a substrate to betransported, and a strip-shaped film is half-cut from its lower surface,it is possible to prevent mixing of dust and dirt.

According to the present invention (first solution), it is unnecessaryto re-load a film piece, and a release film is not cut, so that fastbonding is possible.

According to the present invention (first solution), in which a filmpiece is transported, as it is sucked, to near the site of bonding to asubstrate, it is possible to prevent the workability from being lowereddue to the tendency of a film piece to roll on itself.

According to the present invention (first solution) in which no wastefulcutting chips of polarizing plates are produced, it is possible toincrease the yield of the polarizing plate to 100%.

According to the present invention (first solution) in which a circularpolarized plate film, composed of a phase difference film and apolarizing plate, bonded to each other, can be continuously bonded to asubstrate, and no wasteful cutting chips of a circular polarizedpolarizing plate films are produced, it is possible to increase theyield of a circular polarizing plate film to 100%.

In addition, according to the present invention (first solution), inwhich a film piece is supplied from the lower side of a substrate to betransported, a roll of a strip-shaped film can be exchanged easily.

Meritorious Effect of the Second Solution

According to the present invention (second solution) a polarizing platemay be bonded to each substrate surface continuously and automatically.

According to the present invention (second solution) the operationalspeed may be increased because there is no necessity for re-loading filmpieces, while a release film is not segmented.

According to the present invention (second solution) the yield of 100%is achieved, because no unneeded chips of polarizing plates areproduced. The result is that the cost of a display device may belowered.

According to the present invention (second solution) control may beexercised more easily over the direction of an axis of lighttransmission of a polarizing plate in bonding a polarizing plate on eachsurface of a substrate for a TN substrate.

According to the present invention (second solution) a film for circularpolarization, composed of a phase difference film and a polarizingplate, bonded together, may be continuously bonded to a substrate. Sinceno unneeded chips of a film for circular polarization is produced, a100% yield of a film for circular polarization may be achieved.

According to the present invention (second solution) the overallapparatus may be reduced in size in the case of bonding a polarizingplate simultaneously to each substrate surface.

According to the present invention (second solution) a film piece issupplied from the underside of a substrate to be transported. In caseswhere a strip-shaped film is half-cut from its underside, it is possibleto prevent intrusion of contaminants. Since a strip-shaped film issupplied from the underside of a substrate to be transported, rolls of astrip-shaped film may be exchanged easily.

(Meritorious Effect of the Third Solution)

According to the present invention (third solution), bonding can be madewithout halting film supply, thereby improving the productivity.

According to the present invention (third solution) there is nonecessity of re-loading film pieces, while a release film is not cut, sothat high-speed bonding may be achieved.

According to the present invention (third solution) it is possible toprevent unneeded chips of polarizing plates from being produced, sothat, unless bonding with margin, a 100% yield may be achieved.

According to the present invention (third solution) a film for circularpolarization, obtained on bonding a phase difference film and apolarizing plate, can be continuously bonded to a substrate, such thatunneeded chips of circular polarizing plate film may be prohibited frombeing produced, so that, unless bonding with margin, a 100% yield may beachieved.

According to the present invention (third solution) in cases where afilm piece is supplied from the underside of a substrate to betransported, it is possible to prevent mixing of dust and dirt affixedto a polarizing plate.

According to the present invention (third solution) in cases where astrip-shaped film is supplied from the underside of a substrate to betransported, rolls of the strip-shaped film may be exchanged easily.

(Meritorious Effect of the Fourth Solution)

According to the present invention (fourth solution) bonding can be madewithout halting transportation of a substrate and film supply, therebyimproving the productivity.

According to the present invention (fourth solution) there is nonecessity of re-loading film pieces, while a release film is not cut, sothat high-speed bonding may be achieved.

According to the present invention (fourth solution) since astrip-shaped film is not bonded with a substrate arranged obliquelyrelative to the strip-shaped film, it is possible to prevent unneededselvedges of a polarizing plate from being produced.

According to the present invention (fourth solution) a film for circularpolarization, composed of a phase difference film and a polarizingplate, bonded together, can be continuously bonded to a substrate, sothat selvedges of a film for circular polarization can be prevented frombeing produced.

According to the present invention (fourth solution) in cases where afilm piece is supplied from the underside of a substrate to betransported, it is possible to prevent mixing and falling of dust anddirt affixed to a polarizing plate.

According to the present invention (fourth solution) in cases where astrip-shaped film is supplied from the underside of a substrate to betransported, rolls of a strip-shaped film may be exchanged easily.

It should be noted that other objects, features and aspects of thepresent invention will become apparent in the entire disclosure and thatmodifications may be done without departing the gist and scope of thepresent invention as disclosed herein and claimed as appended herewith.

Also it should be noted that any combination of the disclosed and/orclaimed elements, matters and/or items may fall under the modificationsaforementioned.

1. A polarizing plate bonding method, comprising: a step of cutting atleast a polarizing plate and an adhesive layer of a strip-shaped film,composed of said polarizing plate, a direction of an axis of lighttransmission of which is oriented obliquely relative to a longitudinaldirection of said strip-shaped film, and a release film bonded to saidpolarizing plate, with interposition of said adhesive layer, when aforward end side severed end face of said strip-shaped filmperpendicular to the longitudinal direction of said strip-shaped filmhas traveled a length corresponding to a length of a substrate, to forma film piece so as to leave the release film uncut, a step of separatingsaid release film from the film piece severed by said cutting, and astep of bonding a tacky surface of said film piece freed of said releasefilm to a mating position of said substrate so that a forward end sideend face of the transported substrate is parallel to the pre-severed endface of said film piece while said film piece and said substrate aremoved to the same direction so that the supply of said film piece issynchronized with the transport of said substrate.
 2. The polarizingplate bonding method as defined in claim 1 wherein before said step ofcutting, a strip-shaped film is reeled out from a roll of saidstrip-shaped film of a preset width, composed of a polarizing plate, adirection of an axis of light transmission of which is orientedobliquely relative to a longitudinal direction of said strip-shapedfilm, and a release film bonded to said polarizing plate, withinterposition of said adhesive layer, and said strip-shaped film issending along the longitudinal direction thereof.
 3. The polarizingplate bonding method as defined in claim 1 wherein before said step ofbonding, said film piece is supplied, freed of said release film, inmeeting with the position of said substrate transported.
 4. Thepolarizing plate bonding method as defined in claim 1 wherein said filmpiece is supplied from a lower side of said substrate, transported witha substantially planar plate surface, so that said film piece is bondedto a lower surface of said substrate.
 5. A method for bonding apolarizing plate, comprising: a step of cutting a first strip-shapedfilm including a polarizing plate and a release film bonded thereto withinterposition of an adhesive layer, and a second strip-shaped filmincluding a polarizing plate and a release film bonded thereto withinterposition of an adhesive layer, when pre-severed end faces of saidfirst and second strip-shaped films along a proceeding direction thereofperpendicular to a longitudinal direction have traveled a distancecorresponding to a length of a substrate, so that at least saidpolarizing plates and the adhesive layers of said first and secondstrip-shaped films are severed along a direction perpendicular to alongitudinal direction, with the exception of said release layer whichremains uncut; said first strip-shaped film being supplied from a frontplate surface side of substrate being transported, said secondstrip-shaped film being supplied from a reverse plate surface side of asubstrate being transported; a direction of an axis of lighttransmission of said polarizing plate of said second strip-shaped filmbeing perpendicular to a direction of an axis of light transmission ofsaid polarizing plate of said first strip-shaped film when the releasefilm of said second strip-shaped film is bonded to the release film ofsaid first strip-shaped film; a step of separating said release films ofsaid first and second strip-shaped films, severed by said cutting ofsaid first and second strip-shaped films; and a step of bonding a tackysurface of said first film piece, freed of said release film, to amating front side surface of said first strip-shaped film, so that thesevered end face of said first film piece is parallel to the forward endface along the transport direction of said substrate, and bonding atacky surface of said second film piece, freed of said release film, toa mating reverse side surface of said second strip-shaped film, so thatthe severed end face of said second film piece is parallel to theforward end face along the transport direction of said substrate.
 6. Amethod for bonding a polarizing plate, comprising: a step of separatinga release film from each of a first strip-shaped film and a secondstrip-shaped film, said first strip-shaped film including a polarizingplate and the release film bonded thereto with interposition of anadhesive layer, said first strip-shaped film being supplied from a frontplate surface side of a substrate being transported; said secondstrip-shaped film including a polarizing plate and a release film bondedthereto with interposition of an adhesive layer, said secondstrip-shaped film being supplied from a reverse plate surface side of asubstrate being transported; a direction of an axis of lighttransmission of said polarizing plate of said second strip-shaped filmbeing perpendicular to the direction of the axis of light transmissionof said polarizing plate of said first strip-shaped film when therelease film of said second strip-shaped film is bonded to the releasefilm of said first strip-shaped film; a bonding step of bonding a tackysurface of said first strip-shaped film, freed of said release film, toa mating front plate surface of said substrate so that the proceedingdirection of said first strip-shaped film coincides with the transportdirection of said substrate, and bonding a tacky surface of said secondstrip-shaped film, freed of said release film, to a mating reverse platesurface of said substrate so that a proceeding direction of said secondstrip-shaped film coincides with a transport direction of saidsubstrate; and a cutting step of severing said first strip-shaped filmand the second strip-shaped film, bonded to both surfaces of saidsubstrate by said bonding means, along a direction parallel to forwardor rear end face along the transport direction of said substrate.
 7. Amethod for bonding a polarizing plate, comprising: a step oftransporting a substrate with one end face of said substrateperpendicular to a proceeding direction; a step of bonding a tackysurface of a first film piece, having a polarizing plate, to a matingplate surface piece of said substrate so that a severed end face of saidfirst film piece is parallel to a forward side end face along atransport direction of said substrate; a step of changing the directionof transport of the transported substrate and transporting the substratealong the so changed direction; and a step of bonding a tacky surface ofsaid second film piece to a plate surface of said substrate opposite toa substrate surface to which said first film piece has been bonded, sothat a severed end face of said second film piece is parallel to aforward end face along the transport direction of said substrate; saidsecond film piece including a polarizing plate and being supplied fromthe plate surface of said substrate opposite to the substrate surface towhich said first film piece has been bonded; a direction of an axis oflight transmission of said polarizing plate of said second strip-shapedfilm being perpendicular to a direction of an axis of light transmissionof said polarizing plate of said first strip-shaped film when the tackysurface of said polarizing plate is bonded to the tacky surface of saidfirst strip-shaped film.
 8. A method for bonding a polarizing plate,comprising: a step of transporting a substrate with one end face of saidsubstrate perpendicular to a proceeding direction; a step of cuttingalong a direction parallel to a forward or rear side end face along thetransport direction of said substrate, so that a tacky surface of afirst strip-shaped film, having a polarizing plate, bonded to one matingplate surface of said substrate, so that a proceeding direction of thefirst strip-shaped film is parallel to a forward side end face along thetransport direction of said substrate; a second transport step ofchanging the direction of transport of the transported substrate andtransporting the substrate along the so changed direction; and a step ofcutting along a direction parallel to a forward or rear end face alongthe transport direction of said substrate, to a plate surface of whichopposite to a plate surface carrying the film piece of the firststrip-shaped film has been bonded a tacky surface of said secondstrip-shaped film, so that the severed end face of the secondstrip-shaped film is parallel to an end face along the proceedingdirection of the substrate; said second strip-shaped film having apolarizing plate; said second strip-shaped film being supplied from aplate surface side of said substrate transported by said secondtransport means which is opposite to a substrate surface bonded to saidfirst film piece; an axis of light transmission of said polarizing plateof said second strip-shaped film being perpendicular to an axis of lighttransmission of said polarizing plate of said first strip-shaped filmwhen the release film side of said second strip-shaped film is bonded tothe release film side of said first strip-shaped film.
 9. A method forbonding a polarizing plate, comprising: a step of separating a releasefilm from a strip-shaped film comprised of a polarizing plate and therelease film bonded thereto with interposition of an adhesive layer,said strip-shaped film being supplied from one plate surface of asubstrate being transported; a step of bonding a tacky surface of saidstrip-shaped film, freed of said release film, to a mating plate surfaceof said substrate, so that a proceeding direction of said strip-shapedfilm coincides with the transport direction of said substrate; and astep of severing said strip-shaped film, bonded to one surface of saidsubstrate by said bonding, along a direction parallel to a forward orrear end face along the transport direction of said substrate.
 10. Amethod for bonding a polarizing plate, comprising: a step of separatinga release film from a strip-shaped film comprised of a polarizing plateand the release film bonded thereto with interposition of an adhesivelayer and supplied from one plate surface of a substrate beingtransported, in a state in which at least the polarizing plate and theadhesive layer are pre-severed, with the release film remaining uncut,so that at least one side of a rectangle corresponding in profile tosaid substrate in an area of a film surface is perpendicular to alongitudinal direction of the film so as to provide a selvedge of saidstrip-shaped film other than an inner portion of said rectangle; a stepof bonding a tacky surface of said inner portion of said rectangle ofsaid strip-shaped film, freed of said release film, to a mating platesurface of said substrate, so that the proceeding direction of saidstrip-shaped film coincides with the transport direction of saidsubstrate; and a step of separating said selvedge of said strip-shapedfilm from said substrate.
 11. The method for bonding a polarizing plateas defined in claim 10, wherein a step of cutting at least a polarizingplate and an adhesive layer from a strip-shaped film, comprised of apolarizing plate and the release film bonded thereto with interpositionof said adhesive layer, and supplied from one plate surface of asubstrate being transported, with the release film remaining uncut, sothat at least one side of a rectangle corresponding in profile to saidsubstrate in an area of a film surface is perpendicular to alongitudinal direction of the film, and said release film is separatedfrom the strip-shaped film severed in said step of cutting.
 12. Themethod for bonding a polarizing plate as defined in claim 10 whereinbonding of said inner portion of said rectangle and the separation ofsaid selvedge are carried out simultaneously.
 13. A method for bonding apolarizing plate, comprising: a step of separating a release film from astrip-shaped film comprised of a polarizing plate and the release filmbonded thereto with interposition of an adhesive film, said strip-shapedfilm being supplied from one plate surface of a substrate transported; astep of bonding at least a tacky surface of said strip-shaped film,freed of said release film, to a mating plate surface of said substrate,so that a proceeding direction of said strip-shaped film coincides witha transport direction of said substrate; a step of cutting saidstrip-shaped film within an area in which the strip-shaped film isbonded to said substrate, within a rectangle mating in profile to saidsubstrate, so that at least one side of the rectangle is perpendicularto a longitudinal direction of the film so as to provide a selvedge ofsaid strip-shaped film other than an inner portion of said rectangle;and a step of separating said selvedge of said strip-shaped film fromsaid substrate.